Radiation exposure control for beamforming technologies

ABSTRACT

A circuit arrangement including one or more processors configured to: detect a presence of one or more human object proximities based on sensor data; identify one or more coverage sectors of one or more antenna arrays, operably coupled to the one or more processors, in response to the detected presence of the one or more human object proximities; determine whether radio waves within the one or more identified coverage sectors satisfy a transmit power criteria; select one or more candidate coverage sectors of the one or more antenna arrays based the one or more identified coverage sectors; and determine at least one radio link quality for the radio waves of the one or more candidate coverage sectors.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.16/427,372 filed on May 31, 2019, which is herein incorporated byreference in its entirety.

TECHNICAL FIELD

Various aspects relate generally to methods and devices for radiationexposure control in beamforming technologies.

BACKGROUND

Many emerging communication technologies, such as 5G New Radio (NR) andWiGig, have identified beamforming as a way to increase radio linkstrength. However, while beamforming may increase link sensitivity, itmay also increase RF exposure power to humans. For example, when adevice uses beamforming to focus its transmissions in a narrowdirection, the resulting beam may deliver more radio energy to a focusedarea. When this focused area is pointed at a human user, the device maydeliver high levels of radiation to them. Various regulators, includingthe Federal Communications Commission (FCC) and the InternationalCommission on Non-Ionizing Radiation Protection (ICNIRP), andstandardization bodies like the 3^(rd) Generation Partnership Project(3GPP) have therefore introduced stringent requirements that limit theamount of radiation that a device can deliver to humans.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, like reference characters generally refer to the sameparts throughout the different views. The drawings are not necessarilyto scale, emphasis instead generally being placed upon illustrating theprinciples of the disclosure. In the following description, variousaspects of the disclosure are described with reference to the followingdrawings, in which:

FIG. 1 shows an exemplary general network for wireless communicationsaccording to some aspects;

FIG. 2 shows an exemplary internal configuration of a devicearchitecture according to some aspects;

FIG. 3A and 3B show exemplary beamforming architectures according tosome aspects;

FIG. 4 shows an exemplary wireless communication network withbeamforming devices according to some aspects;

FIG. 5 shows an exemplary internal configuration of a devicearchitecture according to some aspects;

FIG. 6 shows an exemplary flowchart describing a body detection-basedbeam selection according to some aspects;

FIG. 7 shows an exemplary flowchart describing a body detection-basedbeam selection between a terminal device and a gNB according to someaspects;

FIG. 8 shows an exemplary internal diagram a terminal device depictingcomponents for implementing beam selection methods according to someaspects;

FIG. 9 shows an exemplary internal configuration of controller forimplementing beam selection methods according to some aspects

FIG. 10 shows an exemplary flowchart describing a method for acommunication device to determine a beam pair to communicate with asecond device according to some aspects;

FIG. 11 shows an exemplary flowchart describing a method for acommunication device to update a beam pair to communicate with a seconddevice according to some aspects;

FIG. 12 shows an exemplary high-powered beam from a terminal deviceaccording to some aspects;

FIG. 13 shows an exemplary illustration depicting an exemplary beamsweeping scheme according to some aspects;

FIG. 14 shows an exemplary diagram depicting exposure areas andtransmission beam patterns according to aspects;

FIG. 15 shows an exemplary selective beam narrowing and/or wideningscheme according to some aspects;

FIG. 16 shows an exemplary beam-finding reception method for an arrayreception controller to control one or more antenna arrays according tosome aspects;

FIG. 17 shows an exemplary illustration for cluster identification ofantenna array elements for beam-finding reception according to someaspects;

FIG. 18 shows an exemplary internal diagram of a terminal device withcomponents for beam controlling according to some aspects;

FIG. 19 shows an exemplary internal configuration of controller for beamcontrolling according to some aspects;

FIG. 20 shows an exemplary flowchart for determining a transmission beamscheme to use in wireless communications according to some aspects;

FIG. 21 shows an exemplary internal diagram of a terminal device withcomponents for beam-finding reception according to some aspects;

FIG. 22 shows an exemplary internal configuration of controller forbeam-finding reception according to some aspects;

FIG. 23 shows an exemplary flowchart for beam-finding receptionaccording to some aspects;

FIG. 24 shows an exemplary internal configuration of a terminal deviceaccording to some aspects;

FIG. 25 shows an exemplary flowchart for mitigating human RF exposurewith channel switching according to some aspects;

FIG. 26 shows an exemplary scenario of a sensor detecting an objectaccording to some aspects;

FIG. 27 shows an example of constant and time-dependent human exposurepower limits according to some aspects;

FIG. 28 shows an exemplary timing diagram for triggering channelswitches according to some aspects;

FIG. 29 shows an exemplary flow chart for timing channel switches basedon a time-dependent human exposure power limit according to someaspects;

FIG. 30 shows an exemplary flow chart for scheduling data transmissionbased on a time-dependent power limit according to some aspects;

FIGS. 31 and 32 show exemplary methods of performing radiocommunications according to some aspects;

FIG. 33 shows an example of a terminal device selecting sectors forbeamsweeping based on object sensing according to some aspects;

FIG. 34 shows an example of a terminal device selecting sectors forbeamsweeping based on detecting a human object according to someaspects;

FIG. 35 shows an exemplary internal configuration of a terminal deviceaccording to some aspects;

FIG. 36 shows an exemplary flowchart for selecting sectors to beamsweepbased on object sensing according to some aspects;

FIG. 37 shows an exemplary internal configuration of a terminal devicewith a radar sensor that includes the terminal device's antenna arrayaccording to some aspects;

FIG. 38 shows an exemplary internal configuration of a radar sensorusing a terminal device's antenna array according to some aspects; and

FIGS. 39 and 40 show exemplary methods of performing radiocommunications according to some aspects.

DESCRIPTION

The following detailed description refers to the accompanying drawingsthat show, by way of illustration, specific details and aspects ofaspects in which the disclosure may be practiced.

The word “exemplary” is used herein to mean “serving as an example,instance, or illustration.” The words “plurality” and “multiple” in thedescription and claims refer to a quantity greater than one. The terms“group,” “set,” “sequence,” and the like refer to a quantity equal to orgreater than one. Any term expressed in plural form that does notexpressly state “plurality” or “multiple” similarly refers to a quantityequal to or greater than one. The term “lesser subset” refers to asubset of a set that contains less than all elements of the set. Anyvector and/or matrix notation utilized herein is exemplary in nature andis employed for purposes of explanation. Aspects of this disclosuredescribed with vector and/or matrix notation are not limited to beingimplemented with vectors and/or matrices and the associated processesand computations may be performed in an equivalent manner with sets orsequences of data or other information.

As used herein, “memory” is understood as a non-transitorycomputer-readable medium in which data or information can be stored forretrieval. References to “memory” included herein may thus be understoodas referring to volatile or non-volatile memory, including random accessmemory (RAM), read-only memory (ROM), flash memory, solid-state storage,magnetic tape, hard disk drive, optical drive, among others, or anycombination thereof. Registers, shift registers, processor registers,data buffers, among others, are also embraced herein by the term memory.The term “software” refers to any type of executable instruction,including firmware.

The term “terminal device” utilized herein refers to user-side devices(both portable and fixed) that can connect to a core network and/orexternal data networks via a radio access network. “Terminal device” caninclude any mobile or immobile wireless communication device, includingUser Equipments (UEs), Mobile Stations (MSs), Stations (STAs), cellularphones, tablets, laptops, personal computers, wearables, multimediaplayback and other handheld or body-mounted electronic devices,consumer/home/office/commercial appliances, vehicles, and any otherelectronic device capable of user-side wireless communications.

The term “network access node” as utilized herein refers to anetwork-side device that provides a radio access network with whichterminal devices can connect and exchange information with a corenetwork and/or external data networks through the network access node.“Network access nodes” can include any type of base station or accesspoint, including macro base stations, micro base stations, NodeBs,evolved NodeBs (eNBs), gNodeBs, Home base stations, Remote Radio Heads(RRHs), relay points, Wi-Fi/WLAN Access Points (APs), Bluetooth masterdevices, DSRC RSUs, terminal devices acting as network access nodes, andany other electronic device capable of network-side wirelesscommunications, including both immobile and mobile devices (e.g.,vehicular network access nodes, moving cells, and other movable networkaccess nodes). As used herein, a “cell” in the context oftelecommunications may be understood as a sector served by a networkaccess node. Accordingly, a cell may be a set of geographicallyco-located antennas that correspond to a particular sectorization of anetwork access node. A network access node can thus serve one or morecells (or sectors), where the cells are characterized by distinctcommunication channels.

Various aspects of this disclosure may utilize or be related to radiocommunication technologies. While some examples may refer to specificradio communication technologies, the examples provided herein may besimilarly applied to various other radio communication technologies,both existing and not yet formulated, particularly in cases where suchradio communication technologies share similar features as disclosedregarding the following examples. For purposes of this disclosure, radiocommunication technologies may be classified as one of a Short Rangeradio communication technology or Cellular Wide Area radio communicationtechnology. Short Range radio communication technologies may includeBluetooth, WLAN (e.g., according to any IEEE 802.11 standard), and othersimilar radio communication technologies. Cellular Wide Area radiocommunication technologies may include Global System for MobileCommunications (GSM), Code Division Multiple Access 2000 (CDMA2000),Universal Mobile Telecommunications System (UMTS), Long Term Evolution(LTE), General Packet Radio Service (GPRS), Evolution-Data Optimized(EV-DO), Enhanced Data Rates for GSM Evolution (EDGE), High Speed PacketAccess (HSPA; including High Speed Downlink Packet Access (HSDPA), HighSpeed Uplink Packet Access (HSUPA), HSDPA Plus (HSDPA+), and HSUPA Plus(HSUPA+)), Worldwide Interoperability for Microwave Access (WiMax), 5GNew Radio (NR), for example, and other similar radio communicationtechnologies. Cellular Wide Area radio communication technologies alsoinclude “small cells” of such technologies, such as microcells,femtocells, and picocells. Cellular Wide Area radio communicationtechnologies may be generally referred to herein as “cellular”communication technologies.

Unless explicitly specified, the term “transmit” encompasses both direct(point-to-point) and indirect transmission (via one or more intermediarypoints). Similarly, the term “receive” encompasses both direct andindirect reception. Furthermore, the terms “transmit,” “receive,”“communicate,” and other similar terms encompass both physicaltransmission (e.g., the transmission of radio signals) and logicaltransmission (e.g., the transmission of digital data over a logicalsoftware-level connection). For example, a processor or controller maytransmit or receive data over a software-level connection with anotherprocessor or controller in the form of radio signals, where the physicaltransmission and reception is handled by radio-layer components such asRF transceivers and antennas, and the logical transmission and receptionover the software-level connection is performed by the processors orcontrollers. The term “communicate” encompasses one or both oftransmitting and receiving, i.e. unidirectional or bidirectionalcommunication in one or both of the incoming and outgoing directions.The term “calculate” encompass both ‘direct’ calculations via amathematical expression/formula/relationship and ‘indirect’ calculationsvia lookup or hash tables and other array indexing or searchingoperations.

FIGS. 1 and 2 depict a general network and device architecture forwireless communications. In particular, FIG. 1 shows exemplary radiocommunication network 100 according to some aspects, which may includeterminal devices 102 and 104 and network access nodes 110 and 120. Radiocommunication network 100 may communicate with terminal devices 102 and104 via network access nodes 110 and 120 over a radio access network.Although certain examples described herein may refer to a particularradio access network context (e.g., LTE, UMTS, GSM, other 3rd GenerationPartnership Project (3GPP) networks, WLAN/WiFi, Bluetooth, 5G NR,mmWave, etc.), these examples are demonstrative and may therefore bereadily applied to any other type or configuration of radio accessnetwork. The number of network access nodes and terminal devices inradio communication network 100 is exemplary and is scalable to anyamount.

In an exemplary cellular context, network access nodes 110 and 120 maybe base stations (e.g., eNodeBs, NodeBs, Base Transceiver Stations(BTSs), gNodeBs, or any other type of base station), while terminaldevices 102 and 104 may be cellular terminal devices (e.g., MobileStations (MSs), User Equipments (UEs), or any type of cellular terminaldevice). Network access nodes 110 and 120 may therefore interface (e.g.,via backhaul interfaces) with a cellular core network such as an EvolvedPacket Core (EPC, for LTE), Core Network (CN, for UMTS), or othercellular core networks, which may also be considered part of radiocommunication network 100. The cellular core network may interface withone or more external data networks. In an exemplary short-range context,network access node 110 and 120 may be access points (APs, e.g., WLAN orWiFi APs), while terminal device 102 and 104 may be short range terminaldevices (e.g., stations (STAs)). Network access nodes 110 and 120 mayinterface (e.g., via an internal or external router) with one or moreexternal data networks.

Network access nodes 110 and 120 (and, optionally, other network accessnodes of radio communication network 100 not explicitly shown in FIG. 1)may accordingly provide a radio access network to terminal devices 102and 104 (and, optionally, other terminal devices of radio communicationnetwork 100 not explicitly shown in FIG. 1). In an exemplary cellularcontext, the radio access network provided by network access nodes 110and 120 may enable terminal devices 102 and 104 to wirelessly access thecore network via radio communications. The core network may provideswitching, routing, and transmission, for traffic data related toterminal devices 102 and 104, and may further provide access to variousinternal data networks (e.g., control nodes, routing nodes that transferinformation between other terminal devices on radio communicationnetwork 100, etc.) and external data networks (e.g., data networksproviding voice, text, multimedia (audio, video, image), and otherInternet and application data). In an exemplary short-range context, theradio access network provided by network access nodes 110 and 120 mayprovide access to internal data networks (e.g., for transferring databetween terminal devices connected to radio communication network 100)and external data networks (e.g., data networks providing voice, text,multimedia (audio, video, image), and other Internet and applicationdata).

The radio access network and core network (if applicable, such as for acellular context) of radio communication network 100 may be governed bycommunication protocols that can vary depending on the specifics ofradio communication network 100. Such communication protocols may definethe scheduling, formatting, and routing of both user and control datatraffic through radio communication network 100, which includes thetransmission and reception of such data through both the radio accessand core network domains of radio communication network 100.Accordingly, terminal devices 102 and 104 and network access nodes 110and 120 may follow the defined communication protocols to transmit andreceive data over the radio access network domain of radio communicationnetwork 100, while the core network may follow the defined communicationprotocols to route data within and outside of the core network.Exemplary communication protocols include LTE, UMTS, GSM, WiMAX,Bluetooth, WiFi, mmWave, etc., any of which may be applicable to radiocommunication network 100.

FIG. 2 shows an internal configuration of terminal device 102 accordingto some aspects, which may include antenna system 202, radio frequency(RF) transceiver 204, baseband modem 206 (including digital signalprocessor 208 and protocol controller 210), application processor 212,and memory 214. Although not explicitly shown in FIG. 2, in some aspectsterminal device 102 may include one or more additional hardware and/orsoftware components, such as processors/microprocessors,controllers/microcontrollers, other specialty or generichardware/processors/circuits, peripheral device(s), memory, powersupply, external device interface(s), subscriber identity module(s)(SIMs), user input/output devices (display(s), keypad(s),touchscreen(s), speaker(s), external button(s), camera(s),microphone(s), etc.), or other related components.

Terminal device 102 may transmit and receive radio signals on one ormore radio access networks. Baseband modem 206 may direct suchcommunication functionality of terminal device 102 according to thecommunication protocols associated with each radio access network, andmay execute control over antenna system 202 and RF transceiver 204 totransmit and receive radio signals according to the formatting andscheduling parameters defined by each communication protocol. Althoughvarious practical designs may include separate communication componentsfor each supported radio communication technology (e.g., a separateantenna, RF transceiver, digital signal processor, and controller), forpurposes of conciseness the configuration of terminal device 102 shownin FIG. 2 depicts only a single instance of such components.

Terminal device 102 may transmit and receive wireless signals withantenna system 202. Antenna system 202 may be a single antenna or mayinclude one or more antenna arrays that each include multiple antennaelements. For example, antenna system 202 may include an antenna arrayat the top of terminal device 102 and a second antenna array at thebottom of terminal device 102. In some aspects, antenna system 202 mayadditionally include analog antenna combination and/or beamformingcircuitry. In the receive (RX) path, RF transceiver 204 may receiveanalog radio frequency signals from antenna system 202 and performanalog and digital RF front-end processing on the analog radio frequencysignals to produce digital baseband samples (e.g., In-Phase/Quadrature(IQ) samples) to provide to baseband modem 206. RF transceiver 204 mayinclude analog and digital reception components including amplifiers(e.g., Low Noise Amplifiers (LNAs)), filters, RF demodulators (e.g., RFIQ demodulators)), and analog-to-digital converters (ADCs), which RFtransceiver 204 may utilize to convert the received radio frequencysignals to digital baseband samples. In the transmit (TX) path, RFtransceiver 204 may receive digital baseband samples from baseband modem206 and perform analog and digital RF front-end processing on thedigital baseband samples to produce analog radio frequency signals toprovide to antenna system 202 for wireless transmission. RF transceiver204 may thus include analog and digital transmission componentsincluding amplifiers (e.g., Power Amplifiers (PAs), filters, RFmodulators (e.g., RF IQ modulators), and digital-to-analog converters(DACs), which RF transceiver 204 may utilize to mix the digital basebandsamples received from baseband modem 206 and produce the analog radiofrequency signals for wireless transmission by antenna system 202. Insome aspects baseband modem 206 may control the radio transmission andreception of RF transceiver 204, including specifying the transmit andreceive radio frequencies for operation of RF transceiver 204.

As shown in FIG. 2, baseband modem 206 may include digital signalprocessor 208, which may perform physical layer (PHY, Layer 1)transmission and reception processing to, in the transmit path, prepareoutgoing transmit data provided by protocol controller 210 fortransmission via RF transceiver 204, and, in the receive path, prepareincoming received data provided by RF transceiver 204 for processing byprotocol controller 210. Digital signal processor 208 may be configuredto perform one or more of error detection, forward error correctionencoding/decoding, channel coding and interleaving, channelmodulation/demodulation, physical channel mapping, radio measurement andsearch, frequency and time synchronization, antenna diversityprocessing, power control and weighting, rate matching/de-matching,retransmission processing, interference cancelation, and any otherphysical layer processing functions. Digital signal processor 208 may bestructurally realized as hardware components (e.g., as one or moredigitally-configured hardware circuits or FPGAs), software-definedcomponents (e.g., one or more processors configured to execute programcode defining arithmetic, control, and 110 instructions (e.g., softwareand/or firmware) stored in a non-transitory computer-readable storagemedium), or as a combination of hardware and software components. Insome aspects, digital signal processor 208 may include one or moreprocessors configured to retrieve and execute program code that definescontrol and processing logic for physical layer processing operations.In some aspects, digital signal processor 208 may execute processingfunctions with software via the execution of executable instructions. Insome aspects, digital signal processor 208 may include one or morededicated hardware circuits (e.g., ASICs, FPGAs, and other hardware)that are digitally configured to specific execute processing functions,where the one or more processors of digital signal processor 208 mayoffload certain processing tasks to these dedicated hardware circuits,which are known as hardware accelerators. Exemplary hardwareaccelerators can include Fast Fourier Transform (FFT) circuits andencoder/decoder circuits. In some aspects, the processor and hardwareaccelerator components of digital signal processor 208 may be realizedas a coupled integrated circuit.

Terminal device 102 may be configured to operate according to one ormore radio communication technologies. Digital signal processor 208 maybe responsible for lower-layer processing functions (e.g., Layer 1/PHY)of the radio communication technologies, while protocol controller 210may be responsible for upper-layer protocol stack functions (e.g., DataLink Layer/Layer 2 and/or Network Layer/Layer 3). Protocol controller210 may thus be responsible for controlling the radio communicationcomponents of terminal device 102 (antenna system 202, RF transceiver204, and digital signal processor 208) in accordance with thecommunication protocols of each supported radio communicationtechnology, and accordingly may represent the Access Stratum andNon-Access Stratum (NAS) (also encompassing Layer 2 and Layer 3) of eachsupported radio communication technology. Protocol controller 210 may bestructurally embodied as a protocol processor configured to executeprotocol stack software (retrieved from a controller memory) andsubsequently control the radio communication components of terminaldevice 102 to transmit and receive communication signals in accordancewith the corresponding protocol stack control logic defined in theprotocol software. Protocol controller 210 may include one or moreprocessors configured to retrieve and execute program code that definesthe upper-layer protocol stack logic for one or more radio communicationtechnologies, which can include Data Link Layer/Layer 2 and NetworkLayer/Layer 3 functions. Protocol controller 210 may be configured toperform both user-plane and control-plane functions to facilitate thetransfer of application layer data to and from radio terminal device 102according to the specific protocols of the supported radio communicationtechnology. User-plane functions can include header compression andencapsulation, security, error checking and correction, channelmultiplexing, scheduling and priority, while control-plane functions mayinclude setup and maintenance of radio bearers. The program coderetrieved and executed by protocol controller 210 may include executableinstructions that define the logic of such functions.

Terminal device 102 may also include application processor 212 andmemory 214. Application processor 212 may be a CPU, and may beconfigured to handle the layers above the protocol stack, including thetransport and application layers. Application processor 212 may beconfigured to execute various applications and/or programs of terminaldevice 102 at an application layer of terminal device 102, such as anoperating system (OS), a user interface (UI) for supporting userinteraction with terminal device 102, and/or various user applications.The application processor may interface with baseband modem 206 and actas a source (in the transmit path) and a sink (in the receive path) foruser data, such as voice data, audio/video/image data, messaging data,application data, basic Internet/web access data, etc. In the transmitpath, protocol controller 210 may therefore receive and process outgoingdata provided by application processor 212 according to thelayer-specific functions of the protocol stack, and provide theresulting data to digital signal processor 208. Digital signal processor208 may then perform physical layer processing on the received data toproduce digital baseband samples, which digital signal processor mayprovide to RF transceiver 204. RF transceiver 204 may then process thedigital baseband samples to convert the digital baseband samples toanalog RF signals, which RF transceiver 204 may wirelessly transmit viaantenna system 202. In the receive path, RF transceiver 204 may receiveanalog RF signals from antenna system 202 and process the analog RFsignals to obtain digital baseband samples. RF transceiver 204 mayprovide the digital baseband samples to digital signal processor 208,which may perform physical layer processing on the digital basebandsamples. Digital signal processor 208 may then provide the resultingdata to protocol controller 210, which may process the resulting dataaccording to the layer-specific functions of the protocol stack andprovide the resulting incoming data to application processor 212.Application processor 212 may then handle the incoming data at theapplication layer, which can include execution of one or moreapplication programs with the data and/or presentation of the data to auser via a user interface.

Memory 214 may embody a memory component of terminal device 102, such asa hard drive or another such permanent memory device. Although notexplicitly depicted in FIG. 2, the various other components of terminaldevice 102 shown in FIG. 2 may additionally each include integratedpermanent and non-permanent memory components, such as for storingsoftware program code, buffering data, etc.

In accordance with some radio communication networks, terminal devices102 and 104 may execute mobility procedures to connect to, disconnectfrom, and switch between available network access nodes of the radioaccess network of radio communication network 100. As each networkaccess node of radio communication network 100 may have a specificcoverage area, terminal devices 102 and 104 may be configured to selectand re-select between the available network access nodes in order tomaintain a strong radio access connection with the radio access networkof radio communication network 100. For example, terminal device 102 mayestablish a radio access connection with network access node 110 whileterminal device 104 may establish a radio access connection with networkaccess node 112. In the event that the current radio access connectiondegrades, terminal devices 102 or 104 may seek a new radio accessconnection with another network access node of radio communicationnetwork 100; for example, terminal device 104 may move from the coveragearea of network access node 112 into the coverage area of network accessnode 110. As a result, the radio access connection with network accessnode 112 may degrade, which terminal device 104 may detect via radiomeasurements such as signal strength or signal quality measurements ofnetwork access node 112. Depending on the mobility procedures defined inthe appropriate network protocols for radio communication network 100,terminal device 104 may seek a new radio access connection (which maybe, for example, triggered at terminal device 104 or by the radio accessnetwork), such as by performing radio measurements on neighboringnetwork access nodes to determine whether any neighboring network accessnodes can provide a suitable radio access connection. As terminal device104 may have moved into the coverage area of network access node 110,terminal device 104 may identify network access node 110 (which may beselected by terminal device 104 or selected by the radio access network)and transfer to a new radio access connection with network access node110. Such mobility procedures, including radio measurements, cellselection/reselection, and handover are established in the variousnetwork protocols and may be employed by terminal devices and the radioaccess network in order to maintain strong radio access connectionsbetween each terminal device and the radio access network across anynumber of different radio access network scenarios.

Many emerging communication technologies use beamforming techniques toimprove communication performance. These beamforming techniques operateby adjusting the phase of antennas in an array to produce radiationpatterns of constructive and destructive interference. By shaping andsteering these radiation patterns, radio communication devices canachieve high beamforming gains, which can in turn improve radiocommunication reliability and performance. This can be particularlybeneficial in radio communication technologies that operate at highfrequencies, such as millimeter wave (mmWave) technologies. Becausethese radio technologies may operate at carrier frequencies of 30 GHzand above, beamforming gains can be extremely helpful in compensatingfor the high pathloss often experienced at carrier frequencies in theseranges.

Beamforming systems may perform processing in one or both of thebaseband and RF domains to shape antenna array beam patterns. FIGS. 3Aand 3B show two simplified beamforming approaches as deployed for anexemplary four-element antenna array. Although the following descriptionmay focus on a beamforming in the transmit direction, skilled personscan also apply analogous beamforming techniques to achieve beamforminggains in the receive direction.

FIG. 3A illustrates a simplified digital baseband beamformingarchitecture that digitally applies complex beamforming weights(composed of both a gain and phase factor) in the baseband domain. Asshown in FIG. 3A, beamforming controller 302 may receive baseband symbols and subsequently apply a complex weight vector p_(BB)=[α₁ α₂ α₃α₄]^(T) to s to generate p_(BB)s, where each element α_(i), i=1,2,3,4 isa complex weight (comprising a gain factor and phase shift). Eachresulting element [α₁ s α₂s α₃s α₄s]^(T) of p_(BB)s may be basebandsymbol s multiplied by some complex weight α_(i). Beamforming controller302 may then map each element of p_(BB)s to a respective RF chain of RFsystem 304, which may each perform digital to analog conversion (DAC),radio carrier modulation, and amplification on the received weightedsymbols before providing the resulting RF symbols to a respectiveelement of antenna array 306. Antenna array 306 may then wirelesslytransmit each RF symbol. This exemplary model can also be extended to amulti-layer case where a baseband symbol vector s containing multiplebaseband symbols s₁, s₂, etc., in which case baseband precoding vectorp_(BB) may be expanded to a baseband precoding matrix p_(BB) forapplication to baseband symbol vector s. In this case, α_(i), i=1,2,3,4are row vectors, and p_(BB)s=[α₁s α₂s α₃s α₄s]^(T). Thus, aftermultiplying p_(BB) and s, the overall dimension is the same as theoverall dimension at the output of beamforming controller 302. The belowdescriptions thus refer to beamforming controller 302 as p_(BB) andtransmit symbol/vector as s for this reason while this model can beextended to further dimensions as explained.

By manipulating the beamforming weights of p_(BB), beamformingcontroller 302 may be able to utilize each of the four antenna elementsof antenna array 306 to produce a steered beam that has greater beamgain than a single antenna element. The radio signals emitted by eachelement of antenna array 306 may combine to realize a combined waveformthat exhibits a pattern of constructive and destructive interferencethat varies over distances and direction from antenna array 306.Depending on a number of factors (such as antenna array spacing andalignment, radiation patterns, carrier frequency, and the like), thevarious points of constructive and destructive interference of thecombined waveform can create a focused beam lobe that can be “steered”in direction via adjustment of the phase and gain factors α_(i) ofp_(BB). FIG. 3A shows several exemplary steered beams generated byantenna array 306, which beamforming controller 302 may control byadjusting p_(BB). Although only steerable main lobes are depicted in thesimplified illustration of FIG. 3A, beamforming controller 302 may beable to comprehensively “form” the overall beam pattern including nullsand sidelobes through similar adjustment of p_(BB).

Beamforming controller 302 may also perform adaptive beamforming, wherebeamforming controller 302 dynamically changes the beamforming weightsin order to adjust the direction and strength of the main lobe inaddition to nulls and sidelobes. With these adaptive approaches,beamforming controller 302 can steer the beam in different directionsover time, which may be useful to track the location of a moving targetpoint (e.g. a moving receiver or transmitter). In a radio communicationcontext, beamforming controller 302 may identify the location of atarget terminal device 308 (e.g. the direction or angle of terminaldevice 308 relative to antenna array 306) and subsequently adjust p_(BB)in order to generate a beam pattern with a main lobe pointing towardsterminal device 308, thus improving the array gain at terminal device308 and consequently improving the receiver performance. Throughadaptive beamforming, beamforming controller 302 may be able todynamically adjust or “steer” the beam pattern as terminal device 308moves in order to continuously provide focused transmissions to terminaldevice 308 (or conversely focused reception).

In some aspects, beamforming controller 302 may be implemented as amicroprocessor. Beamforming controller 302 therefore may be able toexercise a high degree of control over both gain and phase adjustmentsof p_(BB) with digital processing. However, as shown in FIG. 3A for RFsystem 304 and antenna array 306, digital beamforming configurations mayuse a dedicated RF chain for each element of antenna array 306 (whereeach RF chain performs radio processing on a separate weighted symbolα_(i)s provided by beamforming controller 302); i.e. N_(RF)=N whereN_(RF) is the number of RF chains and N is the number of antennaelements. Because there may be a complex assortment of circuitry in eachRF chain (DAC, amplification, mixing, etc.), these digital beamformingapproaches can be expensive and power-inefficient. These issues may beworsened as the involved number of antennas increases, which may beparticularly problematic for the massive antenna arrays targeted fornext-generation technologies that will include tens or even hundreds ofantenna elements.

Contrasting with the beamforming controller architecture of FIG. 3A,FIG. 3B shows an RF beamforming approach. As shown in FIG. 3B,beamforming controller 302 may provide baseband symbol s to RFtransceiver 304. RF transceiver 304 may perform RF transmit processingon baseband symbol s and provide the resulting symbol s to each of phaseshifters 310. In the example shown in FIG. 3B, phase shifters 310 mayinclude four phase shifters 310 that each apply a respective phase shiftβ₁ to β₄ to s. In some aspects, phase shifters 310 may be analog RFphase shifters that apply their respective phase shifts in the analog RFdomain. Phase shifters 310 may provide the resulting phase-shiftedsymbols β₁s to β₄s to antenna array 306. The respective antennas ofantenna array 306 may wirelessly transmit the phase-shifted symbols.Similar to the operation of FIG. 3A's digital beamformer, FIG. 3B's RFbeamformer may realize a specific antenna pattern by selecting the phaseweights to β₄. Accordingly, beamforming controller 302 may be configuredto select phase weights to such as based on the direction of terminaldevice 308, and provide the phase weights to β₁ to β₄ to phase shifters310 (with the “Control” line shown in FIG. 3B). Beamforming controller302 may therefore steer the main antenna beam towards terminal device308 through proper selection of the phase weights β₁ to β₄. In somecases, the phase weights may be phase-only (e.g., only a phase shiftwith no amplitude change); in other aspects, the phase weights may havea phase and a gain component (e.g., a phase shift and an amplitudegain).

Many technologies may use these beamforming techniques to improvecommunications. For example, beamforming has found numerous applicationsin radar, sonar, wireless communications, radio astronomy, andacoustics. Such beamforming techniques may be particularly useful fortechnologies that use high carrier frequencies, such as 5G New Radio (5GNR) and other mmWave technologies that use extremely high frequency(EHF) operating bands. Because high frequency carriers experience morepathloss than lower frequency carriers, those high frequency carriertechnologies may extensively use beamforming to provide beam gain thatcan compensate for high link attenuation.

However, while beamforming can improve wireless communications byboosting gain, it can have negative effects on human body radiationexposure. Because directional beamforming often focuses an antennaarray's radiation pattern in a certain direction, the resulting beamwill deliver more electromagnetic radiation (EMR). When the beam ispointed at a human body, it can expose the affected area to high levelsof EMR that can be potentially dangerous. Various aspects of thisdisclosure examine mechanisms for limiting human radiation exposure whenusing beamforming technologies.

Regulations on EMR exposure to the human body have been presented formany wireless transmission systems and there are well-establishedprocedures to satisfy these regulations based on human activity (e.g.,base stations near residences) in the traditional context ofnon-beamforming or unidirectional (from the base station side only)beamforming systems. Such approaches include transmission (Tx) powerreduction, where the device reduces its transmission power, and Tx dutycycle, where the device may reduce its transmission payload over time,e.g., engage in sporadic transmissions. However, these approaches failto account for EMR exposure for beamforming from the mobile device side,and furthermore, fail to account for limiting the EMR exposure at themobile device side while also accounting for link qualityconsiderations.

With the advent of bi-directional beamforming systems in new radio (NR)technologies, such as fifth-generation (5G) wireless communicationtechnology where the operating bands include extremely high frequency(EHF), e.g., millimeter waves, the traditional techniques do not providereasonable solutions. The transmit power reduction introduces linkquality issues and causes link failures, which is especially pronouncedin EHF systems with high link attenuation characteristics, which is akey underlying reason for bi-directional beamforming in the first place.The transmit duty cycle reduction may also not be compatible with theprimary purpose of many EHF systems such as 5G—high data-ratecommunication.

Accordingly, communication devices and methods are presented to addressthe challenge of meeting regulations and/or requirements on exposure toEMR in wireless communications, e.g., wireless communication devicesconfigured to communicate via beamforming. In particular, detectionresults, e.g., body detection from sensors embedded in a mobile device(e.g., terminal device 102), are used to trigger a procedure where thedevice indicates a new transmission (Tx)-reception (Rx) beam pair (e.g.,beamform pair) to the other device, e.g., a base station or anothermobile device.

As described above for FIG. 3, beamforming is a signal processingtechnique used to control the directionality of the transmission and/orreception of a signal, such as a radio or sound signal. Thisdirectionality control may be achieved via electronically ormechanically controlled directional antennas. A widely used class ofelectronically-controlled directional antennas is the phased antennaarray, whereby the signal at each array element is phase shifted so thatthe combined signal of an array at a particular angle is eitherconstructively or destructively combined to induce spatial selectivity.For example, antenna 202 of terminal device 102 may be a phased antennaarray to enable the terminal device to communicate via beamformingtechniques.

By controlling the directional pattern of antennas of the antenna array,beamforming can improve signal quality at an intended receiver whilereducing unintended interference to and from other directions.Accordingly, beamforming has found numerous applications in radar,sonar, wireless communications, radio astronomy, and acoustics. Inparticular, it is a key component of 5G wireless communicationtechnology, where the operating bands include EHF, e.g., millimeterwaves, with high link attenuation characteristics.

In communication systems operating at EHF, such as 5G frequency range 2(FR 2) systems, beamforming at both the transmitter and the receiver atboth ends (e.g., at the base station and the terminal device) is highlyuseful and, in some cases, may be necessary to maintain sufficient linkqualities. This concept is described herein as bi-directionalbeamforming. In these bi-directional beamformed systems, the mobiledevice (e.g., terminal device 102) is also configured to employbeamforming for communications. However, since mobile devices typicallyoperate much closer to bodies sensitive to EMR, e.g., the human body,than the base station and since beamforming increases radiated power inthe selected directions, the potential EMR exposure level cansignificantly increase. This has prompted regulatory and guiding bodiessuch as the Federal Communications Commission (FCC) of the United Statesand the International Commission on Non-Ionizing Radiation Protection(ICNIRP) as well as communication standardization bodies such as 3GPP tointroduce stringent requirements and/or recommendations for humanexposure to radio frequency (RF) radiation in the EHF bands. This may bereferred to as the maximum permissible exposure (MPE). A recent trend inMPE regulations is the substantial reduction of the time interval forobserving exposure level, meaning that even a brief over-exposure isless likely to be tolerated.

An alternative to the traditional methods used in unidirectional ornon-beamforming systems is the autonomous mobile device-side Tx beamsteering, whereby the mobile device, upon a detection of nearby humanpresence, may steer its transmission beam away from the estimateddirection of the human body. This approach leverages the device-sidebeamforming capability in bi-directional beamforming systems, and it hasthe potential to maintain link quality and to be suitable for highdata-rate applications while meeting MPE requirements. However, thisapproach does not exploit the potential of bi-directional beamformingsystems to the fullest, in the sense that it may refine the mobiledevice-side beam but does not refine the beam of its communicationpartner, e.g., base station or another mobile device. In other words, itcan optimize a beam but cannot optimize a beam-pair; e.g., it addressesone dimension in a two-dimensional optimization space. For example, ifthe current base station beam direction is such that all possibledevice-side Tx beam directions with meaningful propagation paths towardthe base station are sufficiently blocked by a nearby human body, theautonomous Tx beam steering at the device will not help.

In some aspects, devices and methods for meeting one or more criterion,including at least one of an exposure criterion and/or link qualitycriterion, from the mobile device (terminal device) side in abi-directional beamforming system are presented. This may include thedevices being configured to exploit a Tx-Rx beam pair recovery procedurebased on the detection of an information, such as the nearby presence ofa human body.

In some aspects, devices and methods configured to performcommunications in bi-directional beamforming systems, such as 5Gsystems, implement mechanisms to employ a beam recovery procedure totrigger setting beamforms at both the device and its communicationpartner. In some case, the mobile device (e.g., terminal device 102) maydetect insufficient link quality due to the beam selection at itscommunication partner side, e.g., other mobile devices or base stations,such as gNBs. Additionally, the mobile device (e.g., terminal device102) may be configured with sensing and/or detecting equipment to detecta nearby body (e.g., an animate body such as a human body) to trigger anadjustment of beams at both the mobile device-side and the communicationpartner-side, wherein the new, adjusted beams is performed via a beamrecovery procedure, thereby initiating a mobile device-side re-selectionof the communication partner-side (e.g., gNB) beams as well as thecorresponding mobile device-side beams to establish a new pair of beampairs that meet one or more criterion, e.g., MPE threshold, linkquality, etc.

By employing the mechanisms described herein, the mobile device maysatisfy exposure requirements and regulations while also maintaininglink quality to fully take advantage of the bi-directional beamformingsystem. Unlike autonomous device-side Tx beam steering techniques, themechanisms described herein explore both the mobile device and itscommunication partner (e.g., base station) side degrees of freedom indetermining suitable beam pairs (e.g., UE-gNB beam-pairs) whoseassociated propagation paths sufficiently avoid exposure thresholds.

FIG. 4 shows a communication network 400 with base stations, 110 and120, which may serve terminal devices (e.g., mobile devices, UEs) 102,104, 206, and 208. It is appreciated that communication network 400 maylargely correspond to the network shown in FIG. 1. The illustration inFIG. 4 is exemplary in nature and may be simplified for purposes of thisexplanation.

In communication network 200, both base stations 110, 120 and terminaldevices 102, 104, 206, and 208 are configured to communicate viabeamforming. In other words, they may both have at least one RF chainand multi-antenna arrays as shown in FIGS. 3A-3B. Accordingly, thedevices shown in network 400 are capable of bi-directional beamforming.

For example, terminal device 102 may communicate with base station(e.g., gNB) 110 via the beams shown. The letter “A” may be indicative ofa user's position relative to terminal device 102 and may be detected bythe terminal device via one or more sensors and/or detectors such as apassive infrared sensor, a capacitive sensor, a resistive sensor, anoptical sensor, a piezoelectric sensor, a camera, a microphone, a radarsensor/detector, a proximity sensor, a proximity detector, or the like.As shown in network 400, the beams between terminal device 120 and basestation 110 avoid the user's position. Similarly, base station 120communicates with terminal device's 104, 206, and 208 via the respectivebeam pairs shown in network 400, while also avoiding the respective userpositions indicated by the letters “B,” “C,” and “D” due to thedetection of the user's presence by the respective terminal device.

Additionally, in device to device (D2D) communications, for example,terminal devices 104 and 206 may communicate with each other viabi-directional beamforming while also selecting beams so as to avoid thedetected position of the users (B and C).

FIG. 5 shows an internal configuration of terminal device 102 accordingto some aspects corresponding to FIG. 2 with the additional features ofthe detectors/sensors 516. Although not explicitly shown in FIG. 5, insome aspects terminal device 102 may include one or more additionalhardware and/or software components, such as processors/microprocessors,controllers/microcontrollers, other specialty or generichardware/processors/circuits, peripheral device(s), memory, powersupply, external device interface(s), subscriber identity module(s)(SIMs), user input/output devices (display(s), keypad(s),touchscreen(s), speaker(s), external button(s), camera(s),microphone(s), etc.), or other related components.

The detectors/sensors 516 may be configured to detect an object locatedexternal to the terminal device 102, such as a body subject to MPEregulations, e.g., the user or another human object. Thedetectors/sensors may include, but are not limited to, equipment such asone or more of a passive infrared sensor, a capacitive sensor, aresistive sensor, an optical sensor, a piezoelectric sensor, a camera, amicrophone, a radar sensor, etc. Each of these sensors may be configuredto detect the presence of, for example, a human body in a distinctmanner, e.g., the passive infrared sensor measures infrared light andmay be configured to indicate the presence of a human body based on aknown IR spectrum, the camera may be configured to determine thepresence of a human body via recognition methods, etc. In anotherexample, the sensors and/or detectors may include an mmWave radarproximity sensor, which may be located close to or in one or moreantenna arrays of the antenna system 202, which may be configured todetect human presence in a number of manners. For example, in oneaspect, detection of body movements and tremor by Doppler andmicro-Doppler effects may be detected. In another aspect, a correlationof an object's distance with its reflectivity may be performed, andcompared to values stored in the terminal device (e.g., the reflectivityof human body parts such as tissue may be characterized dependent ondistance thereby allowing the terminal device to determine humanpresence based on the measured target distance and the reflected signalintensity). In a third aspect, the reflectivity of an object may bemeasured across a wide frequency range and the resulting signature canbe compared with the expected response of the reflectivity of a humanbody. In another aspect, a joint decision based on the any combinationof the aspects described above with respect to any of thesensors/detectors may be performed for body detection.

These detectors and/or sensors may be configured to communicate with thebaseband modem 206 via the application processor 212.

FIG. 6 shows a flowchart 600 describing a general method ofbody-detection-based beam recovery performed by a mobile device (e.g.,terminal device 102 or UE) according to some aspects. Flowchart 600illustrates an exemplary scenario showing the operation instance of abody-detection-based beam recovery method in the context ofbi-directional beamforming communications between a mobile device andits communication partner (e.g., a second device, such as a base stationor another mobile device).

The method described in flowchart 600 may be initiated when the devicemakes a directional detection of a nearby body 602. This detection maybe defined as meeting a first criterion of one or more criterion and beperformed after a certain time interval from the last bodydetection-based recovery instance (e.g., the last time the method shownin 600 was performed) by the device. The detection of the nearby bodymay be detected by one or more sensors and/or detectors of the mobiledevice, such as a body proximity sensor (BPS). BPSs include anymechanism that a mobile device, such as terminal device 102, may use tosense or detect a nearby presence of a body, e.g., an animate body suchas a human body or the like, whether the body physically touches thesensor or not. Examples may include, but are not limited to, one or moreof a passive infrared sensor (PIR), a capacitive sensor, a resistivesensor, an optical sensor, a piezoelectric sensor, a camera, amicrophone, a radar sensor, or the like. For example, a PIR sensormeasures infrared light radiated from objects within its field of view,and it can be tuned to certain bodies, e.g., human bodies, by targetingthe range of infrared light emitted by humans, e.g., in the wavelengthrange of 10-15 micrometers. Each of these sensors or detectors has anassociated coverage of directions, e.g., field of view (FOV), which is athree-dimensional angular range within which it reacts to a stimuli, ortarget. Thus, a device with one or more BPSs can, based on the placementand direction of its one or more sensors, associate body detection witha particular direction.

In some aspects, a terminal device may use two or more of these BPSs toincrease its angular and/or distance coverage for detecting nearbybodies. For example, the terminal device may use its camera to cover afirst area, and a PIR sensor to cover a second area, thereby increasingthe area/volume in which the terminal device may detect the presence ofa nearby body, where the sum of the first area and the second area isgreater than each of the areas each of the BPSs would be able to coverindividually. It is appreciated that other BPSs or any number of BPSsmay also be included in this example of increasing the coverage area fordetection.

For example, this detection of the nearby body may be made with respectto the distance to the body (from the mobile device) and the directionof the communication partner device.

Based on the detected information gathered in 602, the mobile device maydetermine a set of test beam directions 604. The test beam directionsmay be chosen based on a second criterion evaluated based on an MPEthreshold requirement. The MPE threshold requirement may be defined interms of power per unit area. For example, the test beams may beselected from a plurality of test beams, wherein the test beams do notexceed the MPE threshold requirement.

The determination of a set of MPE-compliant (or human-avoiding) testbeam directions may be based on the directional body-detection and amapping between the set of candidate body-proximity directions and a setof device beams. The mapping for the terminal device can bepre-determined based on the known directional coverages of one or moreBPSs of the terminal device and the directional coverages of possiblebeams of the terminal device. Such a mapping may allow for theidentification of the beam directions that map to the detected directionof a body, hereafter referred to as “risky” beams for convenience, orequivalently, identifying the beam directions that do not map to thedetected direction of a body, hereafter referred to as “safe” beams. Thedetermined set of MPE-compliant test beam directions (also referred toas the primary beam or a device-side beam of a beam pair) may be asubset of the safe beams. As a non-limiting example, given the knowledgeof risky beams and the antenna panels or arrays that form the riskybeams, referred to as risky panels or arrays, the MPE-compliant set mayexclude all beams formed by the risky antenna panels or arrays, althoughsome of those beams may be safe beams.

In 606, the device measures a channel quality metric based on a set ofsignals from the communication partner device, e.g., reference signals,using the determined test beams. In some aspects, the measurement of thechannel quality metric may be performed after the determination of thetest beams as shown in flowchart 600, or in other aspects, themeasurements may be performed prior to the determination of test beams.In this sense, the measurements may be conducted across all theplurality of test beams, or across a smaller subset that are expected tocontain some beam directions meeting the MPE requirement regardless ofthe direction of the detected information in 602. Therefore, 606 maytake place prior to, or concurrently with, 604.

The measurement of channel quality metrics using the determinedMPE-compliant test beams may be based on reference signals that areconfigured to be used at the device for the purpose of identifyingcandidate partner beams. Examples of the channel quality metricsinclude, but are not limited to: received power, e.g., L1-RSRP (layer-1reference signal received power) in 3GPP standards, determinations ofsignal-to-interference-plus-noise ratio (SINR), and/or a mutualinformation (MI) between a transmitted signal and the correspondingreceived signal which may include, for example, precoding matrixindicator (PMI) and/or channel quality indicator (CQI) information, etc.

Based on the measured channel quality metrics, the device may identify aset of candidate partner device beams for the communication partner anda set of its own candidate beams 608. The candidate partner device beammay be defined as a partner-side beam of the beam pairs and the owndevice beams may be defined as the device-side beam of the beam pair. Inother words, the beam pair for the bi-directional beamforming methodsdescribed herein includes a device-side beam and a partner-side beam,e.g., a pair of beams.

Identification of candidate partner beams and candidate device beams maybe based on the said measured channel quality metrics. For example,after making the measurements with a number of candidate partner-beamand candidate device-beam “pairs,” the terminal device may identify apreferred beam pair whose associated channel quality metric is thehighest and use this as the selected beam pair.

The device may then transmit the candidate partner beam information tothe communication partner device, for example, through a beam recoveryrequest to the communication partner 610. In response to this request,the communication partner may then adjust its beamform configurationbased on the request 612 (adjust to the partner-side beam of the beampair), while the device may adjust its own beamform configurationaccordingly 614 (adjust to the device-side beam of the beam pair). Thetiming of the shift to the beam pair may be according to a timingschedule maintained between the device and the communication partnerdevice. In the context of body-detection-based beam recovery methods ofthis disclosure, the terminal device may switch to the identifiedcandidate device-beam on or before the time-schedule. Such an earlierswitching may be beneficial or necessary to satisfy time-domain aspectsof the MPE requirement. The partner device may switch to thedevice-indicated preferred set of beams or some other beams. The lattercase may arise when the partner device can estimate its own set ofMPE-compliant beams and may thereafter instruct the terminal device toadjust accordingly.

The transmission of the beam recovery request to the communicationpartner may be done according to a standardized procedure supported bythe terminal device and the partner device. Accordingly, in someaspects, the bi-directional beamforming communication systems disclosedherein, such as 5G NR (New Radio) systems, support a device-triggeredbeam recovery procedure, whereby the device indicates a preferred set ofpartner-side beams to the partner device.

The communication partner device may be, for example, a base station(e.g., gNB), a relay node, another mobile device, or any other apparatuscapable of beamformed communication with the terminal device.

FIG. 7 shows a flowchart 700 describing a method of body-detection-basedbeam recovery performed by a mobile device (e.g., terminal device 102, aUE) in the context of a communication between the mobile device and agNB in accordance with 5G NR Release-15 standard according to someaspects. Although shown specifically to explain the bi-directional beamadjustment methods for a mobile device in 5G NR communications, it isappreciated that the methods shown in flowchart 700 may be similarlyapplied to other technologies employing bi-directional beamformingbetween a device and its communication partner.

In 702, the UE may make a directional detection of a nearby body similarto the directional detection of 602 in FIG. 6, e.g., via any one of theBPSs that the UE is equipped with. For example, this detection of thenearby body may be made with respect to the distance to the body (fromthe UE) and the direction of the gNB. The direction of the gNB may, forexample, be determined based on the measurement of downlink (DL) testbeams and/or reference signals.

In 704, the UE may determine a set of test beams from the UE candidatebeam set whose estimated exposure power density on the detected bodyfrom 702 does not exceed an MPE threshold. The MPE threshold may be setforth or based on EMR regulations and/or requirements set forth byregulatory authorities. The UE may be configured to make such adetermination similar to the determination of the set of test beamsdescribed in 604 in FIG. 6. For example, the directional body-detectionmay trigger a determination of a set of MPE-compliant test beamdirections at the UE. This determination may be based on the directionalbody-detection and a mapping between a set of candidate body-proximitydirections and a set of device beams. In some aspects, all risky antennapanels or arrays that may form risk beams are first excluded, and theset of MPE-compliant test beams are constructed from the set of beamsformed by the remaining “safe” antenna panels or arrays.

In 706, the UE may measure the reference signal received power (RSRP)based on a set of downlink reference signals using the determined testbeams. This procedure may correspond to 606 in FIG. 6.

For example, once a set of MPE-compliant test beam directions aredetermined in 704, the UE measures channel quality metrics such asL1-RSRP using the MPE-compliant test beams and based on a set ofcandidate-beam-detection (CBD) reference signal (RS) resources. This setof CBD-RS resources, also known as BFR (beam failure recovery) RSresources, may be configured by the network via radio resource control(RRC) signaling, in particular the candidateBeamRSList field within theRRC information element (IE), BeamFailureRecoveryConfig. The set ofCBD-RS resources may be synchronization signal block (SSB) resourcesdefined via the RRC field BFR-SSB-Resource or channel stateinformation-reference signal (CSI-RS) resources defined via the RRCfield BFR-CSIRS-Resource.

In 708, the UE identifies candidate gNB-beams (e.g., partner-side beamsof the potential beam pairs) and the corresponding paired UE-beams(e.g., device-side beams of the potential beam pairs) based on theL1-RSRP measurements. In a simple example, the UE may identify thecandidate beams based on the beams associated with the highest L1-RSRPmeasurements. This procedure may correspond to 608 in FIG. 6.

In 709, the UE may decide whether to send a beam recovery request to thegNB by considering at least one of a set of estimated downlink (DL) costmetrics and/or uplink (UL) cost metrics. The DL metrics may include, inlayer 1 (L1), an estimated DL throughput loss, e.g., based on DL MIestimation, if the UE does trigger the beam pair switching. For higherlayers (e.g., layer 2 and above), the DL metrics may include anestimation of DL quality of service (QoS) loss if the UE does triggerthe beam pair switching. The UL metrics may include, in L1, anestimation of UL throughput loss if the UE does not trigger beam pairswitching but instead performs a transmission (Tx) power reduction. Forhigher layer, the UL metrics may include an estimation of the UL QoSloss if the UE does NOT trigger beam pair switching but instead performsa Tx power reduction.

In 710, the UE transmits the beam recovery request to the gNB via thephysical random-access channel (PRACH), wherein the PRACH preamblesequence may be associated with the selected gNB-side beam. For example,the UE may transmit the beam recovery request to the gNB via the PRACHin an UL slot “n” according to 5G NR standards.

After the transmission and reception of the beam recovery request in710, the gNB changes it beam(s) based on the received beam recoveryrequest 712 while the UE changes its beam(s) to the selected beam(s) ofthe candidate UE-beams 714. This procedure may include, for example, thegNB to start transmitting DCI (downlink control information) in PDCCH(physical downlink control channel) in the search space indicated viathe RRC field recoverySearchSpaceId in the RRC IEBeamFailureRecoveryConfig, starting from downlink (DL) slot [n·2^(μ)^(DL) /2^(μ) ^(UL) ]+4, where μ_(DL) ∈ {0,1,2,3} and μ_(UL) ∈ {0,1,2,3}denote downlink and uplink subcarrier spacing (SCS) configuration, e.g.,subcarrier spacing Δf=2^(μ)·15 KHz, respectively. Eventually, the gNBmay update active transmission configuration indicator (TCI) states viaa TCI States Activation/Deactivation for UE-specific PDSCH (physicaldownlink shared channel) MAC (medium access control) CE (controlelement). The UE may switch its beams to the identified candidateUE-beams in a corresponding manner.

FIG. 8 shows an internal diagram a terminal device 102 depictingcomponents according to some aspects. Accordingly, the illustrateddepiction of FIG. 8 may omit certain components of terminal device 102that are not directly related to methods described herein. Additionally,components depicted as being separate in FIG. 8 may be incorporated intoa single, hybrid component that performs the same functions as theseparate components, and, similarly, single components may be split intotwo or more separate components that perform the same function as thesingle component.

As shown in FIG. 8, the baseband modem 206 may include an evaluator 806for evaluating one or more criterion as described herein, for example,based on the detection of another body, an MPE threshold, or the like.Baseband modem 206 may include a determiner 804 for determining one ormore beam pairs from a plurality of potential beam pairs to use incommunications with a second device based on the one or more criterion.Determiner 804 may also be configured to transmit an indication of oneor more partner-side beams of a selected beam pair of the one or morebeam pairs to the second device. Baseband modem 206 may include a beamcontroller 806 configured to adjust an antenna configuration of theterminal device to communicate with the second device via a device-sidebeam of the selected beam pair.

For example, the one or more criterion may include determining a bodybased on information provided by one or more detectors/sensors 516,e.g., BPSs. It is appreciated that evaluator 802 may be located in theapplication processor (not shown in FIG. 8, but shown as 212 in FIG. 2)and provide the information to the determiner 804 via an interfacebetween the baseband modem 206 and application processor 212.

FIG. 9 shows an exemplary internal configuration of controller 210according to some aspects. As shown in FIG. 9, controller 210 mayinclude processor 902 and memory 904. Processor 902 may be a singleprocessor or multiple processors, and may be configured to retrieve andexecute program code to perform the transmission and reception, channelresource allocation, and cluster management as described herein.Processor 902 may transmit and receive data over a software-levelconnection that is physically transmitted as wireless radio signals bydigital signal processor 208, RF transceiver 204, and antenna 202.Memory 904 may be a non-transitory computer readable medium storinginstructions for one or more of an evaluation subroutine 904 a, a beamdetermination subroutine 904 b, a beam communication subroutine 904 c,and/or a beam adjustment subroutine 904 d.

Evaluation subroutine 904 a, a beam determination subroutine 904 b, abeam communication subroutine 904 c, and/or a beam adjustment subroutine904 d may each be an instruction set including executable instructionsthat, when retrieved and executed by processor 902, perform thefunctionality of controller 210 and the methods as described herein. Inparticular, processor 902 may execute evaluation subroutine 904 a toevaluate one or more criterion as described herein. For example, the oneor more criterion may include one or more of a detection of a body basedon information gathered and provided by one or more detectors/sensors ofthe terminal device, an MPS threshold, and/or a link quality between theterminal device and a second device, e.g., a base station or a UE.Processor 902 may execute beam determination subroutine 904 b todetermine one or more beam pairs from a plurality of potential beampairs to use in communications with a second device based on the one ormore criterion as described herein. Processors 902 may also execute beamcommunication subroutine 904 c to transmit an indication of one or morepartner-side beams of a selected beam pair of the one or more beam pairsto the second device. Processors 902 may execute beam adjustmentsubroutine 904 d to adjust an antenna configuration of the terminaldevice to communicate with the second device via a device-side beam ofthe selected beam pair. For example, this may include electronicallyadjusting the weights of the antenna array of the terminal device so asto provide for constructive interference to produce the selecteddevice-side beam of the selected beam pair.

FIG. 10 shows an exemplary flowchart 1000 describing a method for acommunication device to determine a beam pair to communicate with asecond device according to some aspects.

The method may include evaluating or more criteria, wherein a firstcriterion of the one or more criterion comprises detecting an object1002, determining one or more beam pairs from a plurality of potentialbeam pairs to use in communications with a second device based on theone or more criteria 1004, transmitting an indication of one or morepartner-side beams of a selected beam pair of the one or more beam pairsto the second device 1006, and adjusting an antenna configuration of thecommunication device to communicate with the second device via adevice-side beam of the selected beam pair 1008.

FIG. 11 shows an exemplary flowchart 1100 describing a method for acommunication device to update a beam pair to communicate with a seconddevice according to some aspects.

The method may include communicating with a second device via adevice-side beam of a beam pair, wherein the second device communicateswith the communication device via a partner-side beam of the beam pair1102, evaluating one or more criteria 1104, and updating a beam pairbased on the evaluation of the one or more criteria, wherein theupdating of the beam pair comprises adjusting the device-side beam to anupdated device-side beam of the updated beam pair, and communicating anupdated partner-side beam of the beam pair to the second device 1106.

For terminal devices operating in the mmWave frequency bands, the actualexposure radio frequency (RF) exposure range to comply with regulationsand/or rules to the human body may be below 15 cm, leading to thepotential for the user to absorb a great deal of the energy on aspecific and isolated part of his/her body. This is particularlydangerous if the beam is highly focused and all the energy is absorbedby a small surface of the human body.

FIG. 12 shows an exemplary illustration showing a concentrated,high-powered beam 1202 from terminal device 102 and the isolated spot1208 of another human body 1206 which may bear the entire brunt of theof the high-powered beam 1202. This “pencil-type” emission beam 1202 istypically highly directive and may result in up to an about 30 dBiantenna gain.

The isolated spot 1208 of the human body 1206, in this example locatedin the head, may be exposed to power density levels in excess ofpermissible power density levels as allowed by regulatory authorities,e.g., maximum power exposure (MPE) thresholds.

Although not shown in FIG. 12, it is also appreciated that the beam 1202may be focused on user 1204 instead, such as when a communicationpartner device (e.g., another UE or a base station) is located on theopposite side of user 1204 as terminal device 102. Accordingly, user1204 may experience even higher levels of power density levels in thisscenario.

Previous solutions include reducing the emission power so that a lowerlevel of energy is absorbed by the user. However, this leads to lowerperformance of the communication system since less energy will bereceived by the target device. This problem is especially pronounced inthe mmWave frequency bands which experience greater problems associatedwith link attenuation.

Accordingly, this disclosure provides methods and devices to account forthis problem. In some aspects, methods and devices are configured toimplement a first scheme to change the emission angle of the beam overtime through controlling the angular diversity of the beam emitted bythe one or more antenna arrays of the terminal device. In this manner,the emitted energy is spread over a larger surface area over timeinstead of pointing continuously to a specific spot for large durationsof time. In some aspects, methods and devices are configured toimplement a second scheme to widen the transmitted beams withoutreducing the transmission power, thereby reducing the power densitylevels experienced by the user. This widening of the beam may alsoprovide the benefit of extra gain due to the uplink signal reflectionsfrom the sidelobes. In some aspects, methods and devices are configuredto dynamically adjust between the first scheme and the second scheme,for example, based on channel parameters such as downlink and/or uplinkchannel measurements. In some aspects, methods and devices areconfigured to perform beam identification at the receiver in anexpeditious manner by identifying the antenna elements of the antennaarray receiving higher levels of energy, and modifying the activelyreceiving antenna elements based on a deviation in the detection of theangle of arrival (AoA) of a received signal.

By implementing these methods and devices, the disclosure providedherein avoids the problem of focusing all the energy of an emitted beamon a specific spot on the user's body, thereby complying with MPEthresholds, while maintaining the directivity and output power levels.Consequently, the overall performance of the system may not (or onlyslightly) be impacted while providing the ability to meet anyregulations and/or standards.

The methods and devices may be configured to detect a human body withthe user of any sensors and/or detectors, e.g., BPSs, as described inFIG. 5.

FIG. 13 shows an illustration depicting a problem scenario 1300 like theone shown in FIG. 12 compared to an exemplary beam sweeping scenario1350 according to some aspects. Although not shown in FIG. 13, it isalso appreciated that the beams 1352-1356 may be focused on user 1204instead, for example, if a communication partner device (e.g., anotherUE or a base station) is located on the opposite side of user 1204 asterminal device 102. Accordingly, user 1204 may experience even higherlevels of power density levels in this since he/she is located closer toterminal device 102.

As shown in 1350, a beam sweeping scheme is implemented by terminaldevice 102 to slightly change the angular direction of beams 1352-1356to spread the energy absorbed by a detected human body 1206 acrossmultiple spots 1352 a-1356 a.

The beam sweeping scheme slightly changes the direction of the beam(e.g., mmWave beam) over time. For example, this may include terminaldevice 102 being configured to time-multiplex the Tx beam angles near aspatial neighborhood of the currently acquired optimal angle ofdeparture (AoD) of the communication partner device, e.g., another UE ora base station. This may have a limited performance loss, if any, on theuplink (UL) traffic, but provides the benefits of meeting MPE thresholdrequirements by distributing the energy absorbed by a user (or otherhuman) over a larger surface, e.g., 1352 a-1356 a.

The communication partner device (not shown, e.g., another UE or a basestation) receiving the transmitted beams 1352 a-1356 a may employ a samebeam/receive configuration to communicate with terminal device 102employing a beam sweeping scheme shown by beams 1352 a-1356 a. In someaspects, the communication partner device may coordinate a timingschedule of the beam sweeping scheme with terminal device 102 a priori,and therefore be configured to adjust its beam configuration/receiveconfiguration accordingly. In some aspects, the communication partnerdevice may be configured to recognize the beam sweeping schedule basedon the terminal device's history and adjust accordingly.

FIG. 14 shows an exemplary illustration 1400 depicting the exposureareas 1402 versus the transmission (Tx) beam patterns 1404 from aterminal device 102 as a function of time according to some aspects.

Although only four beams are shown as part of the beam sweeping schemein illustration 1400, it is appreciated that any number of beams may beused. The time may be determined based on any regulations, standards,and/or rules set forth by regulatory bodies (e.g., FCC) or otherstandards committees (e.g., 3GPP). For example, the time may be 4seconds as set forth by the FCC, so each beam shown in illustration 1400may be used for a duration of 1 second.

As shown in illustration 1400, the alternating Tx beams of beam schememay be scheduled in a round-robin manner whose regulation period can beadapted to the averaging window length for RF exposure power densitylimits, e.g., MPE thresholds. As a result, the equivalent exposure powerdensity per exposure area within the regulated power density averagingtime window is reduced. An important distinction to the beam sweepingschemes described herein, e.g., as shown in illustration 1400, is thatdata is communicated in each of the beams. In other words, the beamsweeping scheme is not simply to identify beams meeting a certaincriterion, but is instead used to transmit information. In this manner,the terminal device may schedule with the communication partner devicethe order of the beam sweeping scheme so as to ensure good linkconditions for the communication of the data.

FIG. 15 shows an exemplary selective beam narrowing and/or wideningscheme 1500 according to some aspects.

Beam 1502 depicts a narrow beam while beam 1504 depicts the wide beam.Arrow 1512 indicates the exposure power density back-off between thenarrow beam 1502 and the wide beam 1504. Arrow 1514 indicates thepotential extra performance gain attainable from reflected uplinksignals from the side-lobes of the widen beam 1504 when compared to thenarrow beam 1502.

In the selective beam widening and/or narrowing scheme, the direction ofthe optimal Angle of Departure (AoD) to the communication partner deviceremains largely, or completely, unchanged. The selection between thewide beam or the narrow beam may further be influenced by the detectionof a human body as described herein. Instead of transmitting a narrow Txbeam with reduced transmission power, the terminal device 102 may widenthe Tx beam pattern from 1502 to 1504 without a reduction in thetransmission power. This reduces the exposure power density in the caseof the detection of a body, for example, by increasing the exposure areawith the widened beam, while maintaining the same level of transmissionpower. This may result is increased signal gain due to the reflected ULsignals from the side lobes.

In some aspects, the terminal device 102 may include a beam controllerconfigured to dynamically select between the beam sweeping scheme andthe selective beam widening and/or narrowing scheme described herein.The dynamic selection may be based on one or more different factors,including, but not limited to: the detection of an object such a humanbody, MPE thresholds, link quality considerations, channel conditions,and/or channel parameters.

Both of the beam sweeping and the selective widening and/or narrowingschemes described herein have extra gains when compared with simplyreducing the transmission power of a narrow Tx beam. Furthermore, withrespect to one another, the beam sweeping scheme generally presentsbetter performance gain in line-of-sight (LoS) channel conditions whilethe beam widening and/or narrowing technique generally presents betterperformance gain in multi-path channels by exploiting the gains from thesignal reflections of the wide-beam side lobes. The dynamic selectionbetween the two schemes may be either open-looped or close-looped.

In some aspects, in an open-loop example, terminal device 102 maydirectly measure the channel parameters (e.g., delay spread) from DLsignals which are spatially associated to the UL channels and compare itwith a pre-defined threshold. In some aspects, in a closed-loop example,when a human body is detected, terminal device 102 may attempt to tryboth schemes and measure the UL quality for each scheme. The UL qualitymeasurement can be based on run-timing UL block error rate (BLER) and ULthroughput measurement of physical uplink shared channel (PUSCH)transmissions. Based on the UL quality measurements, terminal device 102could select the TX beam control scheme with the best UL quality.

In some aspects, in addition to selecting between beam sweeping and beamwidening/narrowing, the beam controller of terminal device 102 may alsobe used to select between different methods of beam widening. Forexample, the widening may be performed in either the horizontal orvertical direction. In a further example, the exact width of thewidening/narrowing may be controlled. In a further example, determiningwhich secondary beams to use for beam sweeping may be controlled.Accordingly, in the beam sweeping schemes described herein, non-adjacentbeams may also be used. For example, a subset of the best beams may beselected and the transmissions may be distributed across this subsetbeams. The highest rated beam of the selected subset may, for example,be selected to transmit data of a higher priority.

By dynamically choosing between the different beam schemes describedherein, the beam controller of the terminal device determining whichbeams to use based on a compromise between gain by reducing the localexposure and loss by having to resort to less optimal beams (be it interms of direction or shape) by adapting suitable parameters like beamwidth, the direction into which to broaden the beam, or the selection ofadjacent or even non-adjacent beams to use. In some aspects, whensweeping between different beams, the sweeping cycle may be designed topreferably switch between nearby beams rather than to jump instantlybetween beams which are further apart. The relevant distance between thebeams or active antenna elements of an antenna array may not beconsidered at the transmission side but only at the reception side.

The different schemes described herein, either individually or in anycombination, may be implemented by communication device with a beamcontroller. For example, the beam controller may be configured toperform a proximity detection and if a user is detected nearby, it maycollect channel state measurements to decide which of the proposedschemes, e.g., the beam sweeping scheme or the selective widening and/ornarrowing scheme, to apply.

The widening and/or narrowing of a beam may be controlled by changingthe number of activated antenna elements within an antenna panel (e.g.each element of antenna array 306 of FIG. 3A-3B, where four antennaelements are shown in each exemplary antenna array). Changing of theangular position of the beam may be controlled by changing the RF systemand/or phase shifter setting of the activated antenna elements within anantenna panel (e.g. RF 304 in FIG. 3A and phase shifters 310 in FIG.3B). The changes of the activated antenna elements and in the phaseshifter setting of the antenna elements are described in further detailwith respect to FIG. 3A-3B.

Furthermore, the beam controller may be fine-tuned to perform each ofthe beam diversity methods (e.g., beam sweeping or thewidening/narrowing) by looking at the Quality of Service (QoS). If thechannel quality is good or meets a certain threshold, the beam might besteered to a direction that will be away from a user but stillguarantees a certain QoS without impacting user experiences. If thechannel quality is bad or below a certain threshold, then the beam maybe narrowed in the direction of the communication partner device.

Each of the beam schemes may also be negotiated between a terminaldevice and its communication partner device, e.g., the base station.However, this may require standardization and a specific communicationprotocol between the devices. In some aspects, the devices and methodsdescribed herein are implemented based on alternating the Tx code-wordswithin the antenna panel. The code-words may be pre-defined and the Txbeam pattern neighborhood information may also be known a priori.

In some aspects, a communication device may include an array receptioncontroller configured to control one or more antenna arrays of thecommunication device according to a beam-finding reception scheme. FIG.16 shows an illustration of a method 1600 according to some aspects.

According to some aspects, in case the transmission angle is altered atthe transmitter of the communication partner device, the receiver if theterminal device 102, whose location is depicted as “UE” in FIG. 16 maybe depicted to perform a method according to 1602-1606. The transmissionangle of the incoming signal is denoted by the angle of arrival (AoA).When the transmission angle is altered, the terminal device detects thechange (e.g., by a differing amount of energy being received by one ormore antenna elements of its antenna system) and triggers a beam-findingapproach highlighted in 1602-1606.

Each time that the transmission angle is altered at the transmitterside, the array reception controller at the communication device mayrestart a beam-finding approach in order to identify the suitablereception cluster, wherein the reception cluster includes one or morereception elements of the antenna array. Since small angular changes inthe transmitter may typically lead to small angular changes of the AoAin the receiver in case of Line-of-Sight propagation and a near-bylocated receiver, the array reception controller may be configured to,instead of restarting the entire identification of the reception clusterprocess from 1602, start the identifying of the reception cluster froman intermediate step, such as in 1604 or 1606, for example. The arrayreception controller may initiate this method based on the assumptionthat the incoming beam is expected to arrive in one of the neighboringclusters, or the same cluster, as the previous reception cluster.

In 1602, the array reception controller may identify that the AoA of theincoming signal is in cluster S1,1. Cluster S1,1 corresponds to a firstsubset of antenna array elements of a plurality of antenna arrayelements of the UE. For example, the first subset may correspond to afirst antenna array of two antenna arrays located in the UE, or half (orany other proportion) of antenna array elements of a single antennaarray.

In 1604, the array reception controller is configured to further narrowdown the array elements associated with the AoA in a further, or second,subset of antenna array elements S2,4, wherein the second subset maylocated within the first subset of antenna array elements. And, in 1606,the array reception controller is configured to further narrow down thearray elements associated with the AoA in a further, or third, subset ofantenna array elements S3,7, wherein the third subset may located withinthe second subset of antenna array elements.

Also, angular changes in the transmitter may be typically cyclicallyrepeated and a small number of different transmission angles may betypically applied. For example, angles “alpha_1,” “alpha_2,” and“alpha_3” may be cyclically applied at the transmitter. Once thecorresponding reception clusters are identified for each of the angles(e.g., “alpha_1”−>Cluster “S_x1,y1,” “alpha_2”−>Cluster “S_x2,y2” and“alpha_3”−>Cluster “S_x3,y3”), the array reception controller may notneed to be repeat the identification of the appropriate receptionclusters in the future, but rather, the array reception controller maybe configured to identify the clusters based on its previous learnings,e.g., the clusters from the previous reception cluster identificationprocesses are reused.

When a small angular change is applied to the transmission beam, thearray reception controller may be configured to anticipate that the newincoming beam may either arrive i) in the current cluster or ii) in aneighboring cluster. It is thus typically sufficient to check theneighboring clusters of incoming energy as illustrated in FIG. 17. Asshown, the array reception controller may only need to perform theidentification of clusters as shown in 1606 instead of starting from1602 every time. And, in case that the checking of neighboring clustersis insufficient for identifying the incoming beam, the array receptioncontroller may be configured to start the overall beam identificationprocess from an earlier step, e.g., 1604 or, in the last resort, 1602.

FIG. 18 shows an internal diagram a terminal device 102 depictingcomponents according to some aspects. Accordingly, the illustrateddepiction of FIG. 18 may omit certain components of terminal device 102that are not directly related to methods described herein. Additionally,components depicted as being separate in FIG. 18 may be incorporatedinto a single, hybrid component that performs the same functions as theseparate components, and, similarly, single components may be split intotwo or more separate components that perform the same function as thesingle component.

As shown in FIG. 18, the baseband modem 206 may include a beamcontroller 1806 for implementing at least one of two beam schemes: abeam sweeping scheme 1804 or a beam widening and/or narrowing scheme1806. In some aspects, the beam controller 1802 may be configured todynamically select between both schemes based on information provided bydetectors/sensors 516 or channel measurements obtained from a channelmeasurer 1808.

FIG. 19 shows an exemplary internal configuration of controller 210according to some aspects. As shown in FIG. 19, controller 210 mayinclude processor 1902 and memory 1904. Processor 1902 may be a singleprocessor or multiple processors, and may be configured to retrieve andexecute program code to perform the transmission and reception, channelresource allocation, and cluster management as described herein.Processor 1902 may transmit and receive data over a software-levelconnection that is physically transmitted as wireless radio signals bydigital signal processor 208, RF transceiver 204, and antenna system202. Memory 1904 may be a non-transitory computer readable mediumstoring instructions for one or more of an angular sweeping subroutine1904 a, a selective beam widening and/or narrowing subroutine 1904 b, ameasurement subroutine 1904 c, and/or a dynamic beam adjustmentsubroutine 1904 d.

Angular sweeping subroutine 1904 a, a selective beam widening and/ornarrowing subroutine 1904 b, a channel measurement subroutine 1904 c,and/or a dynamic beam adjustment subroutine 1904 d may each be aninstruction set including executable instructions that, when retrievedand executed by processor 1902, perform the functionality of controller210 and the methods as described herein. In particular, processor 902may execute angular sweeping subroutine 1904 a to perform the beamsweeping scheme across a plurality of different angles with respect tothe communication device as described herein. Processor 902 mayselective beam widening and/or narrowing subroutine 1904 b to performthe beam widening and/or narrowing beam schemes as described herein.Processors 902 may also execute measurement subroutine 1904 c to providethe at least one of an information from a sensor/detector and/or channelmeasurements for use in the dynamic selection between the schemesdescribed herein. Processors 902 may execute dynamic adjustmentsubroutine 1904 d to adjust dynamically adjust the antenna array systemof the terminal device between the beam sweeping and beam wideningand/or narrowing schemes described herein.

FIG. 20 shows an exemplary flowchart 2000 describing a method for acommunication device to determine a transmission beam scheme to use inwireless communications according to some aspects.

The method may include making one or more measurements 2002; controllingone or more antenna arrays to generate one or more beams according to abeam scheme based on the one or more measurements 2004, wherein the beamscheme implements the one or more beams according to at least one of:over an angular range with respect to the communication device, whereina first beam of the one or more beams has a different angle with respectto the communication device than a second beam of the one or more beams,and each beam of the one or more beams is maintained based on apredetermined time pattern 2006, or a selective widening and/ornarrowing of at least one beam of the one or more beams 2008. In someaspects, the method may further include dynamically adjusting betweenthe beam sweeping and the selective widening and/or narrowing 2010.

The one or more measurements of 2002 may include, for example,measurements made by one or more sensors/detectors for detecting anobstacle (e.g., human body), channel condition measurements (e.g., delayspread, other metrics for determining channel conditions), and/or linkquality measurements.

FIG. 21 shows an internal diagram a terminal device 102 depictingcomponents according to some aspects. Accordingly, the illustrateddepiction of FIG. 21 may omit certain components of terminal device 102that are not directly related to methods described herein. Additionally,components depicted as being separate in FIG. 21 may be incorporatedinto a single, hybrid component that performs the same functions as theseparate components, and, similarly, single components may be split intotwo or more separate components that perform the same function as thesingle component.

As shown in FIG. 21, the baseband modem 206 may include an AoA detector2106 for detecting a change in an angle of arrival of a signal; a subsetcontroller 2104 for controlling a first subset of antenna elements ofthe plurality of antenna elements to receive the signal based on thedetected change, wherein the first subset of antenna elements is fewerin number than the plurality of antenna elements; and a determiner 2106for determining which of the antenna elements in the first subset ofantenna elements reports a suitable reception strength and set the oneor more antenna arrays to the receive scheme based on the determination.

FIG. 22 shows an exemplary internal configuration of controller 210according to some aspects. As shown in FIG. 22, controller 210 mayinclude processor 2202 and memory 2204. Processor 2202 may be a singleprocessor or multiple processors, and may be configured to retrieve andexecute program code to perform the transmission and reception, channelresource allocation, and cluster management as described herein.Processor 2202 may transmit and receive data over a software-levelconnection that is physically transmitted as wireless radio signals bydigital signal processor 208, RF transceiver 204, and antenna system202. Memory 2204 may be a non-transitory computer readable mediumstoring instructions for one or more of a detection subroutine 2204 a, asubset determination subroutine 2204 b, and/or a reception (Rx) antennaarray setting subroutine 2204 c.

Detection subroutine 2204 a, a subset determination subroutine 2204 b,and/or a reception (Rx) antenna array setting subroutine 2204 c may eachbe an instruction set including executable instructions that, whenretrieved and executed by processor 2202, perform the functionality ofcontroller 210 and the methods as described herein. In particular,processor 2202 may execute detection subroutine 2204 a, a subsetdetermination subroutine 2204 b, and/or a reception (Rx) antenna arraysetting subroutine 2204 c according to the methods described herein,e.g., with respect to FIGS. 16, 17, 21, and 23.

FIG. 23 shows an exemplary flowchart 2300 describing a method for acommunication device to set an antenna array receive configurationaccording to some aspects.

The method may include detecting a change in an angle of arrival of asignal 2302, controlling a first subset of antenna elements of theplurality of antenna elements to receive the signal based on thedetected change, wherein the first subset of antenna elements includesless antenna elements than the plurality of antenna elements 2304, anddetermining which of the antenna elements in the first subset of antennaelements reports a suitable reception strength and set the one or moreantenna arrays to the receive scheme based on the determination 2306.

As discussed above, beamforming can concentrate an antenna array'sradiation pattern into a focused beam. While this can providebeamforming gain, it can also increase the level of human RF exposure,such as when beamforming focuses an antenna array's radiation onto auser's body. This may be particularly problematic in emerginghigh-frequency radio technologies such as 5G, which may use beamformingto counteract the pathloss of high-frequency carriers.

To manage human RF exposure, regulatory bodies have introduced morestringent requirements for mmWave technologies. These include the MPErequirements discussed above, such as those specified in the 5G NRstandard. While legacy 3G and 4G technologies were governed only bynear-field RF exposure restrictions, these MPE requirements requireexposure protection in both the near-field and far-field regions of thetransmit antennas (e.g., up to 15 cm depending on RF measurements).

Aspects described above sought to reduce human RF exposure by changingthe beamforming configuration used by a transmitting terminal device,such as by switching the matched transmit-receive beamforming pairbetween a terminal device and network access node or by cyclicallyadjusting a terminal device's beamforming configuration to spread outthe affected area of a human. By contrast, aspects of this disclosuredescribed here seek to reduce human RF exposure by triggering a channelswitch procedure to a narrower bandwidth channel Because the new channelhas narrower bandwidth, the terminal device can reduce its transmitpower without reducing the transmit power density. Since the transmitpower density can be maintained, the terminal device can continue toperform uplink communications with sufficient link quality while alsoreducing human exposure power levels. As described below, these aspectsmay use 5G NR's bandwidth part (BWP) fallback mechanism to trigger achannel switch procedure that switches from a current BWP to a defaultBWP with narrower bandwidth. These aspects can therefore re-purpose 5GNR's BWP fallback mechanism to help mitigate human RF exposure.

FIG. 24 shows an exemplary configuration of terminal device 2400according to some aspects. The configuration shown in FIG. 24 is focusedon the human RF exposure mitigation features of terminal device 2400 andmay not expressly depict other components that are less relevant tothese features. As FIG. 24 shows, terminal device 2400 may includeantenna system 2402, RF transceiver 2404, and baseband modem 2406.Terminal device 2400 may transmit and receive radio signals on one ormore radio access networks. Baseband modem 2406 may direct suchcommunication functionality of terminal device 2400 according to thecommunication protocols associated with each radio access network, andmay execute control over antenna system 2402 and RF transceiver 2404 totransmit and receive radio signals according to the formatting andscheduling parameters defined by each communication protocol. Althoughvarious practical designs may include separate communication componentsfor each supported radio communication technology (e.g., a separateantenna, RF transceiver, digital signal processor, and controller), forpurposes of conciseness the configuration of terminal device 2400 shownin FIG. 24 depicts only a single instance of such components.

Terminal device 2400 may transmit and receive wireless signals withantenna system 2402, which may be a single antenna, an antenna arraythat includes multiple antennas, or multiple antenna arrays that eachinclude multiple antennas. In some aspects, antenna system 2402 mayadditionally include analog antenna combination and/or beamformingcircuitry. In the receive (RX) path, RF transceiver 2404 may receiveanalog radio frequency signals from antenna system 2402 and performanalog and digital RF front-end processing on the analog radio frequencysignals to produce digital baseband samples (e.g., In-Phase/Quadrature(IQ) samples) to provide to baseband modem 2406. RF transceiver 2404 mayinclude analog and digital reception components including amplifiers(e.g., Low Noise Amplifiers (LNAs)), filters, RF demodulators (e.g., RFIQ demodulators)), and analog-to-digital converters (ADCs), which RFtransceiver 2404 may utilize to convert the received radio frequencysignals to digital baseband samples. In the transmit (TX) path, RFtransceiver 2404 may receive digital baseband samples from basebandmodem 2406 and perform analog and digital RF front-end processing on thedigital baseband samples to produce analog radio frequency signals toprovide to antenna system 2402 for wireless transmission. RF transceiver2404 may thus include analog and digital transmission componentsincluding amplifiers (e.g., Power Amplifiers (PAs), filters, RFmodulators (e.g., RF IQ modulators), and digital-to-analog converters(DACs), which RF transceiver 2404 may utilize to mix the digitalbaseband samples received from baseband modem 2406 and produce theanalog radio frequency signals for wireless transmission by antennasystem 2402. In some aspects baseband modem 2406 may control the radiotransmission and reception of RF transceiver 2404, including specifyingthe transmit and receive radio frequencies for operation of RFtransceiver 2404.

FIG. 24 also depicts several internal components of baseband modem 2406,including digital receiver 2408, digital transmitter 2410, controller2412, sensor 2414, and estimator 2416. In some aspects, baseband modem2406 may include a digital signal processor and a protocol controller.Digital receiver 2408, digital transmitter 2410, and controller 2412 maytherefore be subcomponents of the digital signal processor (e.g.,physical layer components) and/or subcomponents of the protocolcontroller (e.g., protocol stack components). In some aspects, digitalreceiver 2408 may be the physical layer receive chain, digitaltransmitter 2410 may be the physical layer transmit chain, andcontroller 2412 may be the protocol controller that executes theprotocol stack of baseband modem 2406. For example, digital receiver2408 may include a demodulator, demapper (e.g., constellation demapper),de-interleaver, decoder, and/or descrambler. Digital receiver 2408 mayreceive wireless signals in the form of baseband samples via antennasystem 2402 and RF transceiver 2404. Digital receiver 2408 may thensequentially process these baseband samples with the demodulator,demapper (e.g., constellation demapper), de-interleaver, decoder, and/ordescrambler to produce a bitstream, which digital receiver 2408 mayprovide to controller 2412 (e.g., to protocol stack layers of controller2412). Digital transmitter 2410 may include a scrambler, encoder,interleaver, mapper (e.g., constellation mapper), and/or a modulator,which may sequentially process a bitstream (e.g., provided by protocolstack layers of controller 2412) to produce baseband samples (e.g.,complex IQ symbols). Digital transmitter 2410 may then transmit thesebaseband samples as wireless signals via RF transceiver 2404 and antennasystem 2402. Controller 2412 may include one or more processorsconfigured to execute the protocol stack layers as software. This mayinclude generating messages for digital transmitter 2410 to transmit(e.g., messages including user or control data) and/or recoveringmessages from bitstreams provided by digital receiver 2408. In someaspects, controller 2412 may be configured to perform user-plane andcontrol-plane functions to facilitate the transfer of application layerdata to and from terminal device 2400 according to the specificprotocols of the supported radio communication technology. User-planefunctions can include header compression and encapsulation, security,error checking and correction, channel multiplexing, scheduling andpriority, while control-plane functions may include setup andmaintenance of radio bearers. The program code retrieved and executed bycontroller 2412 may include executable instructions that define thelogic of these functions. Controller 2412 may also be configured tocontrol beamforming by antenna system 2402. In some aspects, controller2412 may be configured with the features of beamforming controller 302in FIGS. 3A and 3B and may control the digital or RF beamforming ofantenna system 2402. Controller 3512 may therefore select thebeamforming weight vector for antenna system 2402 (either to applydigitally like in FIG. 3A or with RF phase shifters like in FIG. 3B).

Terminal device 2400 may be configured to mitigate human RF exposurewith channel switching. FIG. 25 shows exemplary method 2500, whichterminal device 2400 may execute to perform the human RF exposuremitigation with channel switching in some aspects. As described below,in some aspects terminal device 2400 may use the 5G NR BWP fallbackmechanism as the channel switching mechanism; in other aspects, terminaldevice 2400 may use another available channel switching mechanism (suchas where terminal device 2400 is configured to operate with anotherradio access technology). Terminal device 2400 may use this channelswitching mechanism to switch to a channel with narrower bandwidth,which can enable terminal device 2400 to reduce its transmit powerwithout reducing uplink sensitivity.

Specifically, as shown in FIG. 25 terminal device 2400 may firsttransmit on an activated channel with a first transmit power and a firstantenna beam in stage 2502. For example, controller 2412 of terminaldevice 2400 may specify the first transmit power to digital transmitter2410, and digital transmitter 2410 may then transmit data via RFtransceiver 2404 at the first transmit power. Controller 2412 may alsospecify the activated channel to digital transmitter 2410, and digitaltransmitter 2410 may transmit the data on the activated channelController 2412 may also specify a first antenna beam to digitaltransmitter 2410 and/or to an RF phase shifter array attached to antennasystem 2402 (not explicitly shown in FIG. 24), such as where the firstantenna beam is represented by a first beamforming weight vector.Digital transmitter 2410 may transmit the data with the first antennabeam by applying digital beamforming (e.g., as in FIG. 3A), such as byapplying a the first beamforming weight vector to the data whentransmitting the data; alternatively, digital transmitter 2410 maytransmit the data with the first antenna beam by applying RF beamforming(e.g., as in FIG. 3B), such as where an RF phase shifter array attachedto antenna system 2402 applies the first beamforming weight vector tothe data.

In some aspects, the activated channel may be a bandwidth part (BWP),such as a BWP used in 5G NR. The 5G NR standard specifies that differentBWPs can be assigned to different parts of a wideband carrier. Forexample, a first BWP may be assigned to a first frequency range in thecarrier's bandwidth, a second BWP may be assigned to a second frequencyrange in the carrier's bandwidth, a third BWP to a third section, and soforth. Each BWP can then act as its own channel, and can, for example,have its own bandwidth, subcarrier spacing, symbol duration, and/orcyclic prefix (CP) length. A terminal device that is operating on thecarrier can then select one of the BWPs to use for uplink and/ordownlink communications (e.g., the same or different BWP for uplink anddownlink). In some aspects, the terminal device can select a specificBWP based on the type of communications; for example, a terminal devicethat is receiving bursty traffic (e.g., IP traffic) may select a BWPwith a wider bandwidth. Providing multiple BWPs on a single carrier maytherefore provide flexibility, allowing terminal devices to usedifferent BWPs based on the demands of their current data connections.

5G NR further specifies that the network can configure a terminal devicefor four BWPs in uplink and four BWPs in downlink at a time (e.g., viacontrol signaling from the network access node) but currently limits aterminal device to only one uplink BWP and one downlink BWP active at atime. The network designates one of the configured BWPs the as thedefault uplink BWP. The terminal device can then use the default uplinkBWP for timing advance and to re-synchronize when timing advance islost. In some cases, the network may configure the same BWP as both adefault uplink and downlink BWP; in other cases, the network mayconfigure a default uplink BWP that is different from the defaultdownlink BWP.

In the example of FIG. 25, terminal device 2400 may initially be using anon-default BWP as the activated channel Accordingly, while terminaldevice 2400 may have initially used the default BWP (e.g., a defaultchannel) to determine a timing advance and to establish synchronizationwith the network, terminal device 2400 may have switched to anon-default BWP as the activated channel In this 5G NR example, theactivated channel may be one of the four configured uplink BWPs.

After transmitting on the activated channel, terminal device 2400 maydetect a human object nearby in stage 2504. For example, sensor 2414 maybe configured to sense a human object around terminal device 2400. Asused herein, a human object refers to a whole human body or any part ofa human body (e.g., a hand, a torso, a head, and the like). The humanobject may be the body of a user of terminal device 2400 or a human bodyof a non-user that is near terminal device 2400. In various aspects,sensor 2414 may be an infrared sensor, a capacitive sensor, a resistivesensor, an optical sensor, a piezoelectric sensor, a camera, amicrophone, a radar sensor, or the like. Sensor 2414 may be configuredto perform human object sensing depending on its sensor type. Forexample, the infrared sensor measures infrared light and may beconfigured to detect a human object based on a known IR spectrum, thecamera may be configured to detect a human object via image recognition,the capacitive sensor may be configured to detect a human object byobserving charge variations in a capacitor, and so forth. In someaspects, sensor 2414 may be a mmWave radar sensor, and may use anantenna array of antenna system 2402 to detect a human object (e.g., anantenna array-based radar sensor). This mmWave radar sensor is fullydescribed below in FIGS. 37 and 38. In some aspects, the mmWave radarsensor may be configured to detect human object movements and tremorwith Doppler and micro-Doppler effects. In some aspects, the mmWaveradar sensor may be configured to correlate a blocking object's distancewith its reflectivity, and to distinguish between human and non-humanblocking objects by comparing the correlation to values stored in theterminal device (e.g. the reflectivity of human body parts such astissue may be characterized dependent on distance thereby allowing theterminal device to determine human presence based on the measured targetdistance and the reflected signal intensity). In some aspects, themmWave radar sensor may measure the reflectivity of an object across awide frequency range and may compare the resulting signature with theexpected response of the reflectivity of a human object. In someaspects, the mmWave radar sensor may combine multiple of Doppler,correlation of distance with reflectivity, and frequency responsereflectivity signatures to detect human bodies.

Sensor 2414 may use any of these techniques (or multiple of thesetechniques) to detect a human object. Based on the detection, sensor2414 may obtain human object sensing information that describes theorientation of the detected human object. For example, sensor 2414 mayobtain a distance value for the distance between terminal device 2400and the detected human object. Sensor 2414 may also obtain a directionvalue that represents the direction of the detected human objectrelative to terminal device 2400. The direction can be, for example, anangular direction or a vector direction that expresses where thedetected human object is relative to terminal device 2400. This distancevalue and direction value can be the human object sensing information.

FIG. 26 shows an example of sensor 2414 detecting a human objectaccording to some aspects. As shown in FIG. 26, terminal device 2400 maytransmit data to network access node 2602 (e.g., using the firsttransmit power and the first antenna beam; antenna beam 2604 is shown inFIG. 26). Sensor 2412 may then detect human object 2606 and may obtainhuman object sensing information that represents the location of humanobject 2606 relative to terminal device 2400. The human object sensinginformation may, for example, include a distance value for the distancebetween terminal device 2400 and human object 2606 and a direction valuefor the direction of human object 2606 relative to terminal device 2400.

After detecting the human object, sensor 2414 may provide the humanobject sensing information to estimator 2416. Estimator 2416 may thenestimate a human RF exposure power based on the first transmit power,the first antenna beam, and the human object sensing information instage 2506. The estimated human exposure power (estimated RF exposurepower to a human body) may be an estimated amount of RF energy from theantenna beam that hits the human object, such as a value of unitsmWatts/cm² (or, equivalently, any unit of power over area). Estimator2416 may be a processor configured to calculate an estimated humanexposure power based on these input parameters, and may use any of anumber of estimation techniques to calculate the estimated humanexposure power. For example, estimator 2416 may base its estimation onwhether the detected human object's location (represented by the humanobject sensing information) overlaps with the first antenna beam. FIG.26 shows an example of this, where antenna beam 2604 hits human object2606 (e.g., human object 2606 falls within the path of antenna beam2604). Estimator 2416 may estimate the human exposure power to have alarger value when the detected human object has a larger spatial overlapwith the first antenna beam, and may estimate the human exposure powerto have a smaller value when the detected human object has a smallerspatial overlap with the first antenna beam. Estimator 2416 may also,for example, base its estimation on the distance between terminal device2400 (e.g., between the antenna array of terminal device 2400 that istransmitting the data) and the detected human object. For instance,estimator 2416 may estimate the human exposure power to have a largervalue when the detected human object is closer to terminal device 2400,and may estimate the human exposure power to have a smaller value whenthe detected human object is farther from terminal device 2400.Estimator 2416 may also, for example, base its estimation on the firsttransmit power that terminal device 2400 is using to transmit the data.For instance, estimator 2416 may estimate the human exposure power tohave a larger value when the first transmit power is larger, and mayestimate the human exposure power to have a smaller value when the firsttransmit power is smaller. In some aspects, estimator 2416 may estimatethe human exposure power by detecting the distance between the detectedhuman object and the antenna array and then offsetting the firsttransmit power based on the distance.

Estimator 2416 may provide the estimated human exposure power tocontroller 2412. Controller 2412 may then compare the estimated humanexposure power with an exposure power threshold in stage 2508 anddetermine whether the estimated human exposure power is greater than orbelow the exposure power threshold. In some aspects, the exposure powerthreshold may be, or may be based on, a standardized exposure powerthreshold. For example, the exposure power threshold may be an MPEthreshold, such as an MPE threshold specified by a regulatory body likethe Federal Communications Commission (FCC) or the InternationalCommission on Non-Ionizing Radiation Protection (ICNIRP). In anotherexample, the exposure power threshold may be set to a slightly lowervalue than a regulatory threshold, such as to provide a tolerance range.

Controller 2412 may then proceed to stage 2510 or 2512 based on whetherthe estimated human exposure power is greater than or less than theexposure power threshold. As shown in FIG. 25, if the estimated humanexposure power is greater than the exposure power threshold, controller2412 may trigger a channel switch to a second channel with narrowerbandwidth and may reduce the first transmit power to a second transmitpower in stage 2510. In a general example, controller 2412 may sendsignaling to the network access node that triggers a channel switch fromthe activated channel to a second channel, where the second channel hasnarrower bandwidth than the activated channel Controller 2412 may alsoreduce the first transmit power to a second transmit power and instructdigital transmitter 2410 and RF transceiver 2404 to use the secondtransmit power to transmit subsequent data to the network access node.In some aspects, after triggering the channel switch, controller 2412may receive uplink grants from the network that assign terminal device2400 to transmit on the second channel These uplink grants mayoptionally specify the second transmit power. For example, the networkmay linearly assign transmit power based on the allocated bandwidth, andso may instruct terminal device 2400 to use the second transmit powerwhen transmitting on the second channel. Controller 2412 may thencontrol terminal device 2400 to transmit according to the secondtransmit power specified in the uplink grant. Alternatively, controller2412 may select the second transmit power independently (e.g., withoutreceiving an explicit instruction from the network to use the secondtransmit power). In some aspects, controller 2412 may configure digitaltransmitter 2410 for transmission on the second channel, such as byspecifying the channel parameters (e.g., frequency range, subcarrierspacing, symbol duration, and/or CP length) for the second channelDigital transmitter 2410 may then modulate data (e.g., perform PHY layerprocessing on the data) and transmit the data on the second channel viaRF transceiver 2404 and antenna array 2402. In some aspects, controller2412 may continue to use the first antenna beam when digital transmitter2410 transmits the data on the second channel (e.g., may not change thefirst antenna beam). In some aspects, the data that digital transmitter2410 transmits on the second channel may be part of the same uplink datastream (e.g., on the same radio bearer, part of the same dataconnection, or to the same end location or server) as the data thatdigital transmitter 2410 previously transmitted on the first channel

Conversely, if controller 2412 determines that the estimated humanexposure power is less than the exposure power threshold, controller2412 may continue transmitting on the activated channel with the firsttransmit power. For instance, because the estimated human exposure powerwas below the exposure power threshold, there may not be reason tochange the transmission configuration (e.g., no reason to reduce thebandwidth or transmit power).

With this procedure, terminal device 2400 may reduce the human exposurepower without weakening the radio link and causing coverage issues. Forexample, if terminal device 2400 only reduced the transmit power (fromthe first transmit power to the second transmit power) and did notswitch to a narrower bandwidth, the power density per resource element(e.g., per subcarrier and symbol) would decrease; in other words,reducing the transmit power without reducing bandwidth will decrease theamount of power per unit frequency (the power spectral density).Reducing the power spectral density reduces the SNR, and can in turncause coverage issues and make it difficult for the network access nodeto recover the transmitted uplink data.

By contrast, with the procedure of method 2500, terminal device 2400 canreduce the transmit power without significantly decreasing the powerspectral density. Specifically, terminal device 2400 switches to asecond channel with narrower bandwidth and reduces the transmit power.Terminal device 2400 can therefore maintain, or even increase, the powerspectral density, and as a result can maintain a strong link with thenetwork access node. In some aspects, terminal device 2400 may reducethe data rate (e.g., reduce throughput) when transmitting data on thesecond channel with the second transmit power, since it can be difficultto transmit data at the same rate without seeing data loss. In eithercase, terminal device 2400 may reduce the transmit power, andconsequently reduce the human exposure power, without significantlyimpairing the transmit link.

As previously indicated, in a general example terminal device 2400 mayexchange signaling with the network access node to perform the channelswitch from the activated channel to the second channel with narrowerbandwidth. In one example of this, controller 2412 of terminal device2400 may consider multiple channels and identify one of those channelswith a narrower bandwidth than the activated channel These multiplechannels may be configured so the channels occupy different frequencyranges (e.g., non-overlapping bandwidths, such as for 5G NR BWPs).Controller 2412 may select that channel as the second channel, and maysend signaling to the network access node that triggers a channel switchfrom the activated channel to the second channel Controller 2412 mayoptionally receive signaling from the network access node that confirmsthe channel switch to the second channel, and may then perform thechannel switch to the second channel

In an example for 5G NR or other technologies with a BWP fallbackmechanism, controller 2412 may utilize BWP fallback as the channelswitching mechanism in stage 2510. BWP fallback is a standardized 5G NRprocedure that terminal devices can use when they lose uplink timingwith the network. Specifically, when a 5G NR terminal device is using anon-default BWP and loses its uplink timing (e.g., from timing advancedrift), it can send a random access transmission (e.g., a physicalrandom access channel (PRACH) transmission) to the gNodeB on the defaultBWP. The terminal device can base the random access transmission (e.g.,its preamble sequence) on a beam index that represents the antenna beamthat the terminal device is using. This signals to the gNodeB that theterminal device has lost timing and needs to re-establish its timingadvance. The gNodeB then schedules uplink grants (e.g., physical uplinkshared channel (PUSCH) grants) on the default BWP for the terminaldevice, and uses the antenna beam identified by the random accesstransmission for receiving uplink data from the terminal device. Theterminal device then performs uplink transmission on the default BWPaccording to the uplink grants.

This procedure, known as BWP fallback, is therefore intended to addressuplink timing loss. Aspects of this disclosure, however, re-purpose BWPfallback to trigger a channel switch from the activated channel to thesecond channel For example, digital transmitter 2410 may initially beusing a BWP that is not the default BWP (a non-default BWP) as theactivated channel in stage 2502. If controller 2412 determines that theestimated human exposure power is greater than the exposure powerthreshold in stage 2508, controller 2412 may use BWP fallback as thechannel switching mechanism in stage 2510. Specifically, controller 2412may control digital transmitter 2410 to transmit a random accesstransmission (PRACH) on the default BWP (e.g., also using a predefinedbeam index of the first antenna beam to generate a preamble sequencethat identifies the first antenna beam). The network access node mayreceive the random access transmission on the default BWP and recognizethat terminal device 2400 is triggering BWP fallback. The network accessnode may register the BWP fallback and may start sending uplink grants(PUSCH grants) to terminal device 2400 on the default BWP. Digitalreceiver 2408 may receive these uplink grants (via RF transceiver 2404)and provide them to controller 2412. Controller 2412 may configuredigital transmitter 2410 to transmit on the default BWP, and digitaltransmitter 2410 may transmit data on the default BWP (the secondchannel). This may deactivate the activated BWP and switch all uplinktransmission to the default BWP. As previously described, controller2412 may also reduce the first transmit power (used earlier fortransmitting on the default BWP) to a second transmit power, and digitaltransmitter 2410 and RF transceiver 2404 may transmit the data on thedefault BWP with the second transmit power. Since the default BWPgenerally has the narrowest bandwidth of the configured BWPs, this BWPfallback likely restrict the maximum bandwidth allocation of uplinkchannels (e.g., the number of resource blocks allocated for PUSCH) forterminal device 2400. Transmit power is linearly scaled with the numberof allocated resource blocks so terminal device 2400 will reduce itstransmit power when it switches to the default BWP. Terminal device 2400will therefore deliver less RF energy the human object and cause less RFexposure damage. Even though terminal device 2400 reduced it transmitpower, it can maintain uplink sensitivity because it also reduced itstransmission bandwidth. In some cases, controller 2412 may maintain thesame first antenna beam (e.g., unless separate factors like mobilityindependently trigger a beam change).

Default BWP may therefore serve as the channel switching mechanism.However, while the default BWP often has the narrowest bandwidth out ofthe configured uplink BWPs, in some cases it may not. Accordingly, insome aspects controller 2412 may first compare the bandwidth of theactivated BWP to the bandwidth of the default BWP before triggering achannel switch in stage 2510. If the default BWP's bandwidth is narrowerthan the activated BWP's bandwidth, controller 2412 may trigger thechannel switch using BWP fallback. Conversely, if the default BWP'sbandwidth is wider than the activated BWP's bandwidth, BWP fallback maynot cause a channel switch to a narrower bandwidth. In that scenario,controller 2412 may decide not to trigger a channel switch and mayinstead reduce the first transmit power to a second transmit power andstart transmitting on the activated channel with the second transmitpower. Controller 2412 may select the second transmit power based on theestimated human exposure power from stage 2506, such as by selecting asecond transmit power that will reduce the human exposure power to bebelow the exposure power threshold. Since controller 2412 could not useBWP fallback to switch to a BWP with narrower bandwidth and could onlyreduce the transmit power, this procedure may reduce the power spectraldensity of terminal device 2400's transmissions. Accordingly, this manyreduce uplink sensitivity and cause coverage issues; however, terminaldevice 2400 may not have an alternative option because there may not bean available mechanism for terminal device 2400 to trigger BWP fallbackto a BWP with narrower bandwidth.

In some aspects, controller 2412 may consider the default BWP'sbandwidth size when deciding whether to trigger a channel switch instage 2510. For example, in some cases the default BWP may haveconsiderably smaller bandwidth than the activated BWP. As a result,switching to the default BWP may cause a significant drop in bandwidth,which may impair terminal device 2400's ability to continue transmittingdata (e.g., without having to drop the throughput to an unacceptably lowlevel). Accordingly, controller 2412 may decide in stage 2510 whether totrigger a channel switch based on how much narrower the default BWP'sbandwidth is than the activated BWP's bandwidth. If the default BWP'sbandwidth is too narrow (e.g., less than a predetermined percent of theactivated BWP's bandwidth, such as 25%, 50%, 75%, or the like; less thana predetermined number of resource blocks; or less than a predeterminedbandwidth), controller 2412 may decide not to trigger a channel switch,and may instead continue transmitting on the activated BWP with areduced transmit power.

In some aspects, uplink and downlink communications may be locked to thesame BWP. In other words, terminal device 2400 may be constrained to usethe same BWP for both uplink and downlink (e.g., the network mayconfigure terminal device 2400 to use the same BWP as the default uplinkand downlink BWP, or may generally lock device 2400 to use the same BWPfor uplink and downlink at all times). As a result, when terminal device2400 performs BWP fallback to the default BWP for uplink, terminaldevice 2400 also has to switch its downlink reception to the defaultBWP. If the default BWP has narrower bandwidth, downlink throughput maydrop, which may not be acceptable in certain scenarios (e.g., ifterminal device 2400 is streaming heavy data). Accordingly, in thesescenarios controller 2412 may consider whether the default BWP cansupport ongoing downlink reception (e.g., whether the default BWP cansupport a minimum throughput level used by the ongoing downlinkconnection) when it decides whether to trigger a channel switch. If thedefault BWP can support the downlink reception, controller 2412 maytrigger the channel switch in stage 2510. Conversely, if the default BWPcannot support the downlink reception, controller 2412 may decide not toperform the channel switch in stage 2510. Furthermore, in some aspectscontroller 2412 may consider the potential downlink performancedegradation versus the potential uplink performance degradation whendeciding to perform a channel switch in stage 2510. For instance, whenterminal device 2400 is locked to the same uplink and downlink BWP,there may be a downlink performance degradation if controller 2412triggers BWP fallback: because the default BWP often has narrow (or thenarrowest) bandwidth, the default BWP may have lower downlinkthroughput, deeper fading, and/or more channel interference. Conversely,there may be an uplink performance degradation if controller 2412 doesnot trigger BWP fallback: because terminal device 2400 will continue totransmit on the same bandwidth but need to reduce its transmit power,there will be lower uplink power spectral density and thus a higheruplink error rate. Controller 2412 may therefore consider the tradeoffbetween uplink and downlink performance degradation when deciding totrigger the BWP fallback. In some aspects, controller 2412 may estimatethe potential downlink performance degradation from triggering BWPfallback (e.g., based on throughput, fading, and/or channel interferencefor the default BWP) and estimate the potential uplink performancedegradation from not triggering BWP fallback (e.g., based on uplinkerror rate for the default BWP). Controller 2412 may then decide whetherto trigger BWP fallback based on the potential downlink performancedegradation and the potential uplink performance degradation.

With these aspects, terminal device 2400 may be able to mitigate humanRF exposure by reducing its transmit power. Moreover, by triggering achannel switch to a channel with narrower bandwidth, terminal device2400 may maintain uplink sensitivity (by maintaining, increasing, oronly slightly reducing the uplink power spectral density) and may avoiduplink coverage issues.

In some aspects, controller 2412 may time the channel switch based on atime-dependent human exposure power limit. For example, the FCCregulates human RF exposure with a static human exposure power limit,meaning that the power limit is constant over time and that a terminaldevice should not exceed that limit at any point in time. By contrast,other regulatory bodies like the ICNIRP have also proposed newtime-dependent human exposure power limits (e.g., the ICNIRP exposurecategory termed “brief exposure”). These time-dependent human exposurepower limits allow for different human power exposure levels atdifferent times. For example, a time-dependent exposure power limit mayinitially allow a high level of human exposure power that isincreasingly restricted as a human is exposed to RF over a longer periodof time. FIG. 27 shows an example of the human exposure power limits(“P-limit”) proposed by the FCC and the ICNIRP. As shown in FIG. 27, theFCC may use a constant human exposure power limit 2702, which forbidsterminal devices from causing human exposure power that exceeds aconstant value at any time. The ICNIRP, by contrast, uses atime-dependent human exposure power limit 2704 that varies the permittedhuman exposure power over time. The ICNIRP's time-dependent humanexposure power limit may initially permit a high level of human exposurepower but may increasingly restrict the human exposer power as timepasses. The time-dependent human exposure power limit in FIG. 27 iscyclical, meaning that a terminal device that initially causes a higherlevel of exposure may have to wait a cool-off period before causing highexposure levels again (e.g., until the cyclical time-dependent exposurepower limit resets). In other words, the time-dependent human exposurepower limit may only budget for a certain amount of exposure per cycle(e.g., over one second, or over another cycle duration), and a terminaldevice that uses up most of its budget will need to restrict its humanexposure power until the cycle (and budget) reset. To generalize, thetime-dependent human exposure power limit may specify a high humanexposure power limit during a first time window and may specify a lowerhuman exposure power limit during a second time window.

As introduced above, in some aspects controller 2412 may time thechannel switch based on a time-dependent human exposure power limit. Forexample, the time-independent human exposure power limit may havecertain time windows that permit high levels of human exposure power.Because terminal device 2400 is permitted to transmit at high powerduring these time windows, it may be disadvantageous to cause a channelswitch that occurs around these high exposure power limit windows.Controller 2412 may therefore trigger channel switches so they occuraround low exposure power limit windows.

FIG. 28 shows an example of how controller 2412 of terminal device 2400may trigger channel switches based on a time-dependent human powerexposure limit. FIG. 28 includes the same human exposure power limits2702 and 2704 of FIG. 27, where human exposure power limit 2702 isconstant and where human exposure power limit 2704 is time-dependent. Asintroduced immediately above, controller 2412 may trigger channelswitches so they occur after high exposure power limit windows andaround low exposure power limit windows. FIG. 29 shows an exemplary flowchart illustrating that process according to some aspects. As shown inFIG. 29, controller 2412 may first decide to perform a channel switchfrom an activated channel (e.g., an activated BWP) to a second channelwith narrower bandwidth (e.g., the default BWP) in stage 2902. In oneexample, controller 2412 may make this decision in stage 2510 of FIG.25, where controller 2412 decides to trigger a channel switch based onthe estimated human exposure power being greater than the exposure powerthreshold. Then, after deciding to perform a channel switch in stage2902, controller 2412 may identify a high exposure power limit windowthat is scheduled before a low exposure power limit window in stage2904. Using time-dependent power limit 2704 as an example, controller2412 may identify high exposure power limit window 2806 and low exposurepower limit window 2808. High exposure power limit window 2806 may bepositioned around a section of time-dependent exposure power limit 2704that is high (allowing a higher level of human exposure power) while lowexposure power limit window 2808 may be positioned around a section oftime-dependent exposure power limit 2704 that is low (restricting thehuman exposure power to lower levels). The curve of time-dependentexposure power limit 2704 is exemplary and, to generalize, controller2412 may identify the high exposure power limit window as any section ofa time-dependent exposure power limit that is considerably higher than asubsequent section of the time-dependent exposure power limit. In someaspects, the high exposure power limit window may be immediately beforethe low exposure power limit window.

After identifying the high and low exposure power limit windows,controller 2412 may in stage 2906 identify a first timepoint based on achannel switch latency and the end timepoint of the high exposure powerlimit window. As to the channel switch latency, controller 2412 may knowin advance approximately how long it takes between when controller 2412triggers a channel switch and when the channel switch actually occurs.For example, controller 2412 may transmit control signaling to thenetwork access node that triggers the channel switch at a first time,and the channel switch may actually take place at a later time; in otherwords, the network access node may start sending uplink grants for thesecond channel to terminal device 2400 after some delay has occurred. Ina BWP fallback example, controller 2412 may control digital transmitter2410 to transmit a random access transmission on the default BWP at afirst time, and the network access node may send PUSCH grants toterminal device 2400 that permit terminal device 2400 to starttransmitting on the default BWP at a second later time. That differencebetween the first time (when the channel switch is triggered) and thesecond time (when the channel switch takes effect) is the channel switchlatency.

Because high exposure power limit window 2806 allows terminal device2400 to transmit at high power without violating the exposure limits, itmay be advantageous for terminal device 2400 to trigger the channelswitch so it takes effect after most of high exposure power limit window2806 is over (e.g., right before or around when low exposure power limitwindow 2808 starts). Accordingly, controller 2412 may identify the firsttimepoint so the channel switch takes effect after most of high exposurepower limit window 2806 is over (or, e.g., at or after low exposurepower limit window 2808 starts). Controller 2412 may therefore identifythe first timepoint based on the endpoint of high exposure power limitwindow 2806. In some aspects, controller 2412 may identify the firsttimepoint by identifying a second timepoint, such as timepoint 2804 inFIG. 28, when controller 2412 wants the channel switch to occur. Thesecond timepoint may be after most of high exposure power limit window2806 is over, at or after low exposure power limit window 2808 starts,or around the endpoint of high exposure power limit window 2806.Controller 2412 may then subtract the channel switch latency from thesecond timepoint to obtain the first timepoint (e.g., where the firsttimepoint is separated from the second timepoint by the channel switchlatency).

After identifying the first timepoint in stage 2906, controller 2412 maytrigger the channel switch at the first timepoint in stage 2908. In ageneral example, controller 2412 may send to the network access node atthe first timepoint control signaling that triggers the channel switch;in a BWP example, controller 2412 may send to the gNodeB at the firsttimepoint a PRACH transmission that triggers BWP fallback. Due to thechannel switch latency, the channel switch may then occur at or aroundthe second timepoint (as the channel switch latency may be approximateor unpredictable). In the example of FIG. 28, the channel switch maytake effect at timepoint 2804, which is slightly before low exposurepower limit window 2808 starts. Controller 2412 may then starttransmitting on the second channel (with narrower bandwidth than theactivated channel), and may reduce the first transmit power to a secondtransmit power (e.g., with lower throughput).

With this procedure, terminal device 2400 may transmit at high powerduring high exposure power limit window 2806, and may therefore notviolate the time-dependent exposure power limit 2704. Once thetime-dependent exposure power limit 2704 transmissions to the stricterlow exposure power limit window 2808, terminal device 2400 may have itstransmit power restricted to a significantly lower level. To avoidviolating the stricter exposure power limit, terminal device 2400 maytrigger the channel switch in advance so terminal device 2400 can switchto a narrower bandwidth channel around when low exposure power limitwindow 2808 starts. This may be preferable to case where terminal device2400 does not consider the time-dependent exposure power limit whentriggering channel switches. For example, if terminal device 2400 wereto not consider the time-dependent exposure power limit when triggeringchannel switches, terminal device 2400 could inadvertently trigger achannel switch that takes effect right before or during the beginning ofhigh exposure power limit 2806. Even though terminal device 2400 couldbe transmitting at higher power on larger bandwidth had it not switchedchannels, it would end up switching to a narrower bandwidth channel andreducing its power. With this procedure terminal device 2400 can avoidthat scenario.

In some aspects, controller 2412 may schedule data transmission based ontime-dependent power limits like those described above for ICNRIP. FIG.30 shows exemplary flow chart 3000 illustrating that procedure accordingto some aspects. As shown in FIG. 30, controller 2412 may first identifya high exposure power limit window and a low exposure power limit windowin a time-dependent exposure power limit in stage 3002. Using theexample of FIG. 28, controller 2412 may identify high exposure powerlimit window 2806 and low exposure power limit window 2808 intime-dependent exposure power limit 2704. To generalize, controller 2412may identify, as the high exposure power limit window, a window intime-dependent exposure power limit 2704 that has higher power thanother windows of time-dependent exposure power limit 2704. Controller2412 may then identify, as the low exposure power limit window, a windowin time-dependent exposure power limit 2704 that has lower power thanthe high exposure power limit window.

Controller 2412 may then identify data packets that are scheduled fortransmission in stage 3004. For example, controller 2412 may performscheduling operations for terminal device 2400, such as by executing aMAC layer scheduler program. Controller 2412 may therefore control whendigital transmitter 2410 transmits data packets via RF transceiver 2404.In some aspects, controller 2412 may have a buffer of data packetsscheduled for transmission, and may identify these data packets in stage3004.

Controller 2412 may then in stage 3006 determine transmission times forthe data packets based on the time-dependent exposure power limit andeither a data packet priority or a data packet size. In an example usingdata packet priority, controller 2412 may identify a first data packetand a second data packet that has a lower priority than the first datapacket. For example, the first data packet may have a first QoSrequirement and the second data packet may have a first QoS requirementthat has a lower priority than the first QoS requirement. In someaspects, the QoS requirements may be QoS requirements from a cellularstandard or an IP standard and may be assigned to the data packets byhigher communication layers (e.g., IP or transport layers). Controller2412 may then assign to the first data packet a transmission time thatis in the high exposure power limit window and may assign to the seconddata packet a transmission time that is in the low exposure power limitwindow. In other words, controller 2412 may assign the higher-prioritydata packet to the high exposure power limit window and thelower-priority data packet to the low exposure power limit window. Thismeans that, when terminal device 2400 transmits the first and seconddata packets, the first data packet will likely have a higher transmitpower than the second data packet (e.g., the uplink transmit power willbe larger, and will have a larger power margin during the high exposurepower limit window). This may be advantageous because the first datapacket has higher priority and can be transmitted with higher transmitpower, increasing the probability that the network access node willsuccessfully receive and decode it. Accordingly, terminal device 2400may use data packet priority to schedule data packets for transmissionso that data packets with higher priorities are scheduled for andtransmitted during high exposure power limit windows of thetime-dependent exposure power limit.

Controller 2412 may use a similar technique to schedule transmissiontimes for data packets based on data packet size. In one example,controller 2412 may identify a first data packet and a second datapacket that has a smaller packet size than the first data packet. Forexample, the first data packet may have a first packet size (e.g., inbytes) and the second data packet may have a second packet size that issmaller than the first packet size. Controller 2412 may then assign tothe first data packet a transmission time that is in the high exposurepower limit window and may assign to the second data packet atransmission time that is in the low exposure power limit window. Inother words, controller 2412 may assign the larger data packet to thehigh exposure power limit window and the smaller data packet to the lowexposure power limit window. As a result, when terminal device 2400transmits the first and second data packets, the first data packet willlikely have a higher transmit power than the second data packet. Thismay be advantageous because the first data packet has larger size andcan be transmitted with higher transmit power, increasing theprobability that the network access node will successfully receive anddecode it. Accordingly, terminal device 2400 may use data packet size toschedule data packets for transmission so that data packets with largersizes are scheduled for and transmitted during high exposure power limitwindows of the time-dependent exposure power limit.

Controller 2412 may thus assign respective transmission times to thedata packets in stage 3006. Controller 2412 may then transmit the datapackets at the respective transmission times in stage 3008. For example,controller 2412 may provide the data packets to digital transmitter 2410and control digital transmitter 2410 to transmit each data packet at itsrespective transmission time. Digital transmitter 2410 may then transmitthe data packets via RF transceiver 2404.

FIG. 31 shows exemplary method 3100 of performing radio communicationsaccording to some aspects. As shown in FIG. 31, method 3100 includestransmitting data on a first channel with a first antenna beam and afirst transmit power (stage 3102), determining an estimated radiofrequency (RF) exposure power to a human object based on the firstantenna beam and the first transmit power (stage 3104), determiningwhether the estimated RF exposure power is greater than an exposurepower threshold (stage 3106), and if the estimated RF exposure power isgreater than the exposure power threshold, switching from the firstchannel to a second channel with narrower bandwidth and transmittingdata on the second channel with a second transmit power lower than thefirst transmit power (stage 3108).

FIG. 32 shows exemplary method 3200 of performing radio communicationsaccording to some aspects. As shown in FIG. 32, method 3200 includesidentifying a high exposure power limit window and a low exposure powerlimit window in a time-dependent exposure power limit (stage 3202),identifying a first data packet and a second data packet scheduled fortransmission (stage 3204), determining a first transmission time for thefirst data packet and a second transmission time for the second datapacket based on the time-dependent exposure power limit and furtherbased on a data packet priority or a data packet size (stage 3206), andtransmitting the first data packet at the first transmission time andtransmitting the second data packet at the second transmission time(stage 3208).

As introduced above, radio access technologies such as WiGiG and 5G NRmmWave use beamforming to compensate for the higher pathloss at highfrequency carriers. This beamforming can help achieve the required linkSNR to establish and maintain radio links. Many mmWave systems plan toimplement this beamforming with large antenna arrays, with some systemseven targeting arrays with hundreds of elements. Due to the large numberof radiating elements, these antenna arrays may have very high spatialcoverage and directional resolution.

When devices use beamforming, they may execute a beam selectionprocedure to select a desired beam. Some beamforming systems, such WiGigand 5G NR mmWave, use beamsweeping to select the best directionalantenna beam, or “sector,” for a wireless link. In some cases, a networkaccess node and a terminal device may perform a broad sweep (e.g., asector level sweep (SLS)), such as where a network access node sends outa signal and a terminal device performs a measurement with each sectorof its antenna array (e.g., tunes its antenna array to receive adirectional antenna beam that defines the sector). Based on thosemeasurements, the terminal device can identify the sector that providesthe best signal quality (e.g., link quality). The terminal device canthen configure its antenna array to receive with this selected sector.In various cases, the terminal device and network access node mayreverse this procedure to identify a receive sector for the networkaccess node to use, or may sweep in the transmit direction to identifyoptimal transmit sectors. In some cases, such as WiGig's beam refinementprotocol (BRP), the network access node and terminal device can furtherevaluate the selected sector to select optimal parameters for thatsector (e.g., to narrow or adapt the directional antenna beam in thatsector to further improve link quality).

However, the massive antenna arrays used in some mmWave systems may makethese beamsweeping procedures complex and time-consuming. For example,when the number of antennas and directional resolution (e.g., number ofavailable sectors) is large, a brute-force search that examines eachpossible sector can take a significant amount of time. Since theterminal device performs measurements on each sector, the terminaldevice may also expend considerable battery power while performing thebeamsweeping search. Moreover, because the terminal device will not knowthe best sector until the beamsweeping is finished, the system cansuffer from performance degradation, or even link loss, while thebeamsweeping procedure is pending. Furthermore, the beamsweepingprocedures share the wireless medium with the actual data link, whichmeans that long beamsweeping procedures can cut into time that couldotherwise be used to transfer data.

For these reasons, it can be beneficial to minimize beamsweeping timeand to reduce the power expended by terminal devices duringbeamsweeping. Accordingly, in some aspects of this disclosure a terminaldevice may use object sensing to identify sectors that are blocked byobjects or human bodies. The terminal device may then skip these sectorsduring the beamsweeping. Some aspects may also use the object sensing toidentify which sectors may be sensitive to retransmit power restrictionsdue to the presence of human bodies. For example, a terminal device maydetect a human object in a given sector and then consider how much itwould need to reduce its transmit power in that sector in order tocomply with maximum human exposure power limits. Some aspects may alsoimplement the sensor using the actual antenna array, such as a mmWaveradar sensor that uses the same antenna array for object sensing andwireless communication.

FIG. 33 shows an example according to some aspects that illustrates howa terminal device can reduce the beamsweeping time or power penaltybased on object sensing. As shown in FIG. 33, terminal device 3306 maybe connected with (or in the process of establishing a connection to)network access node 3302. Network access node 3302 and terminal device3306 may be configured to use beamforming to transmit and receivesignals with each other. Accordingly, network access node 3302 mayinclude antenna array 3304 and may use antenna array 3304 to steer adirectional antenna beam towards terminal device 3308; in other words,network access node 3302 may steer the directional antenna beam ofantenna array 3304 in a certain sector that points to terminal device3306. Similarly, terminal device 3306 may include antenna arrays 3308and 3310, which may be positioned on different locations of terminaldevice 3306 (e.g., on a top side of and a bottom side of the handset).While terminal device 3306 has two antenna arrays in this example, inother examples terminal device 3306 may have only one antenna array, ormay have more than two antenna arrays. Terminal device 3306 may operateits antenna arrays similar to network access node 3302. For example,terminal device 3306 may select one of antenna arrays 3308 or 3310 andsteer its directional beam in a certain sector toward network accessnode 3302.

As previously introduced, beamforming systems often use beamsweepingtechniques to select the sectors for directional antenna steering. In anexample of brute-force beamsweeping, network access node 3302 andterminal device 3306 may control their respective antenna arrays to testout each sector. By evaluating each sector, network access node 3302 andterminal device 3306 may identify sectors to use for transmission andreception. For example, network access node 3302 may select a sector ofantenna array 3304 while terminal device 3306 may select a sector ofeither antenna array 3308 or antenna array 3310 (e.g., whicheverprovides the overall best sector).

Testing out each possible sector pair, however, may take a considerableduration of time. While the example in FIG. 33 only shows seven sectorsper antenna array, advanced antenna arrays may have extremely highdirectional resolution and may support hundreds of sectors. Accordingly,in some aspects terminal device 3306 may use object sensing to reducethe beamsweeping time or power penalty. As shown in FIG. 33, there maybe an object that blocks certain paths between terminal device 3306 andnetwork access node 3306. Because this object attenuates radio signalsalong these blocked paths, it is unlikely that the beamsweepingprocedure will select a sector that points toward any of the blockedpaths. In turn, there may be little benefit in analyzing those sectorsduring beamsweeping. Terminal device 3306 can therefore reduce thebeamsweeping time or power penalty by avoiding or skipping testing ofthose sectors during beamsweeping. Using the example of FIG. 33,terminal device 3306 may use its sensor and determine that sensordirection B is blocked by object 3312. Terminal device 3306 may thendetermine that sectors 4 and 5 of antenna array 3308 overlap with sensordirection B but that the other sectors of antenna array 3308, as well asthe sectors of antenna array 3310, are not blocked.

Terminal device 3306 may therefore test these unblocked sectors duringbeamsweeping but may not test blocked sectors 4 and 5. This may savetime and/or battery power. As shown in FIG. 33, network access node 3302may select sector 5 of antenna array 3304 as providing the highest linkquality (denoted by the degree of shading), and terminal device 3306 mayselect sector 9 of antenna array 3310. After finishing the beamsweepingand any further beam refinement, network access node 3302 and terminaldevice 3306 may transmit and receive to each other using the selectedsector pair. These techniques are described below in full.

Some aspects may also consider whether a blocking object is a humanobject (e.g., part or whole of a human body). FIG. 34 shows an exampleaccording to some aspects. In this example, terminal device 3306 mayinclude a sensor configured to detect objects and to distinguish betweenhuman and non-human objects. As shown in FIG. 34, the sensor of terminaldevice 3306 may detect object 3402 in sensor direction A and maydetermine that object 3402 is a human object. Because sectors 1-3 ofantenna array 3308 overlap directionally with sensor direction A,terminal device 3306 may to reduce its transmit power in thesedirections so its transmissions comply with human exposure powerrestrictions (e.g., MPE and SAR). Accordingly, even if terminal device3306 e determines during beamsweeping that sectors 1-3 have the highestlink quality with network access node 3302, sectors 1-3 may be subjectto transmit power restrictions and terminal device 3306 may selectanother sector. Using the example of FIG. 34, terminal device 3306 maydetermine that sectors 1-3 have the highest link quality but are blockedby human object 3402 while sector 4 has lower link quality but is notblocked by a human object. Because sectors 1-3 may be subject withtransmit power restrictions, terminal device 3306 may select sector 4 touse with network access node 3302. In some aspects, terminal device 3306may be configured to weight, or prioritize, certain sectors based onwhether they are blocked by a human object. This is further described inthe examples below.

This disclosure now describes these beamsweeping aspects in detail. FIG.35 shows an exemplary internal configuration of terminal device 3306according to some aspects and FIG. 36 shows an exemplary flow chart 3600that terminal device 3306 may execute. Starting with FIG. 35, thedepicted configuration is focused on the beamsweeping control featuresof terminal device 3306 and may not expressly depict other componentsthat are less relevant to these features. As FIG. 35 shows, terminaldevice 3306 may include antenna system 3502, RF transceiver 3504, andbaseband modem 3506. Terminal device 3306 may transmit and receive radiosignals on one or more radio access networks. Baseband modem 3506 maydirect such communication functionality of terminal device 3306according to the communication protocols for with each radio accessnetwork, and may control antenna system 3502 and RF transceiver 3504 totransmit and receive radio signals according to the formatting andscheduling parameters defined by each communication protocol. Althoughsome designs may include separate communication components for eachsupported radio communication technology (e.g., a separate antenna, RFtransceiver, digital signal processor, and controller), for purposes ofconciseness the configuration of terminal device 3306 shown in FIG. 35depicts only a single instance of these components.

Terminal device 3306 may transmit and receive wireless signals withantenna system 3502, which may be a single antenna or an antenna arraythat includes multiple antennas. In some aspects, antenna system 3502may include multiple antenna arrays, such as is shown in FIG. 33 forantenna arrays 3308 and 3310. In some aspects, antenna system 3502 mayadditionally include analog antenna combination and/or beamformingcircuitry (e.g., a set of phase shifters for phased-array beamforming).In the receive (RX) path, RF transceiver 3504 may receive analog radiofrequency signals from antenna system 3502 and perform analog anddigital RF front-end processing on the analog radio frequency signals toproduce digital baseband samples (e.g., In-Phase/Quadrature (IQ)samples) to provide to baseband modem 3506. RF transceiver 3504 mayinclude analog and digital reception components including amplifiers(e.g., Low Noise Amplifiers (LNAs)), filters, RF demodulators (e.g., RFIQ demodulators)), and analog-to-digital converters (ADCs), which RFtransceiver 3504 may utilize to convert the received radio frequencysignals to digital baseband samples. In the transmit (TX) path, RFtransceiver 3504 may receive digital baseband samples from basebandmodem 3506 and perform analog and digital RF front-end processing on thedigital baseband samples to produce analog radio frequency signals toprovide to antenna system 3502 for wireless transmission. RF transceiver3504 may thus include analog and digital transmission componentsincluding amplifiers (e.g., Power Amplifiers (PAs), filters, RFmodulators (e.g., RF IQ modulators), and digital-to-analog converters(DACs), which RF transceiver 3504 may utilize to mix the digitalbaseband samples received from baseband modem 3506 and produce theanalog radio frequency signals for wireless transmission by antennasystem 3502. In some aspects baseband modem 3506 may control the radiotransmission and reception of RF transceiver 3504, including specifyingthe transmit and receive radio frequencies for operation of RFtransceiver 3504.

FIG. 35 also depicts several internal components of baseband modem 3506,including digital receiver 3508, digital transmitter 3510, controller3512, and sensor 3514. In some aspects, baseband modem 3506 may includea digital signal processor and a protocol controller (e.g., such as inFIG. 2). Digital receiver 3508, digital transmitter 3510, and controller3512 may therefore be subcomponents of the digital signal processor(e.g., physical layer components) and/or subcomponents of the protocolcontroller (e.g., protocol stack components). In some aspects, digitalreceiver 3508 may be the physical layer receive chain, digitaltransmitter 3510 may be the physical layer transmit chain, andcontroller 3512 may be the protocol controller that executes theprotocol stack of baseband modem 3506. For example, digital receiver3508 may include a demodulator, demapper (e.g., constellation demapper),de-interleaver, decoder, and/or descrambler. Digital receiver 3508 mayreceive wireless signals in the form of baseband samples via antennasystem 3502 and RF transceiver 3504. Digital receiver 3508 may thensequentially process these baseband samples with the demodulator,demapper (e.g., constellation demapper), de-interleaver, decoder, and/ordescrambler to produce a bitstream, which digital receiver 3508 mayprovide to controller 3512 (e.g., to protocol stack layers of controller3512). Digital transmitter 3510 may include a scrambler, encoder,interleaver, mapper (e.g., constellation mapper), and/or a modulator,which may sequentially process a bitstream (e.g., provided by protocolstack layers of controller 3512) to produce baseband samples (e.g.,complex IQ symbols). Digital transmitter 3510 may then transmit thesebaseband samples as wireless signals via RF transceiver 3504 and antennasystem 3502. Controller 3512 may include one or more processorsconfigured to execute the protocol stack layers as software. This mayinclude generating messages for digital transmitter 3510 to transmit(e.g., messages including user or control data) and/or recoveringmessages from bitstreams provided by digital receiver 3508. In someaspects, controller 3512 may be configured to perform user-plane andcontrol-plane functions to facilitate the transfer of application layerdata to and from terminal device 3306 according to the specificprotocols of the supported radio communication technology. User-planefunctions can include header compression and encapsulation, security,error checking and correction, channel multiplexing, scheduling andpriority, while control-plane functions may include setup andmaintenance of radio bearers. The program code retrieved and executed bycontroller 3512 may include executable instructions that define thelogic of these functions.

Controller 3512 may also be configured to control beamforming by antennasystem 3502. In some aspects, controller 3512 may be configured with thefeatures of beamforming controller 302 in FIGS. 3A and 3B and maycontrol the digital or RF beamforming of antenna system 3502. Controller3512 may therefore select the beamforming weight vector for antennasystem 3502 (either to apply digitally as in FIG. 3B or with RF phaseshifters as in FIG. 3B). This can include selecting a sector, such asthe sectors described in FIGS. 33 and 34, and configuring antenna system3502 to transmit and/or receive signals with the selected sector.

As introduced above, terminal device 3306 may be configured to performbeamsweeping using object sensing to reduce the beamsweeping time orpower penalty. FIG. 36 shows exemplary flow chart 3600 according to someaspects, which terminal device 3306 may execute for beamsweeping. Asshown in FIG. 36, beamsweeping may be triggered in stage 3602. In someaspects, terminal device 3306 may trigger beamsweeping, such as wherecontroller 3512 transmits signaling to network access node 3302 thattriggers a beamsweeping procedure. For example, controller 3512 maytrigger beamsweeping when terminal device 3306 is first connecting tothe network (e.g., initial network access), such as where terminaldevice 3306 first connects to network access node 3302 and triggersbeamsweeping to find a sector pair for transmitting and receiving withnetwork access node 3302. In another example, controller 3512 may detectthat the radio link with network access node 3302 fails or degrades.Controller 3512 may then trigger beamsweeping with network access node3302 to find another sector pair that can restore the radio link.

In other aspects, network access node 3302 may trigger the beamsweeping,such as where network access node 3302 transmits to terminal device 3306signaling that triggers the beamsweeping. Like the examples above, insome cases network access node 3302 may trigger the beamsweeping whenterminal device 3306 initially connects to network access node 3302; inother cases, network access node 3302 may trigger the beamsweeping whenthe radio link with terminal device 3306 fails or degrades.

After controller 3512 detects that beamsweeping is triggered in stage3602, controller 3512 may instruct sensor 3514 to sense blocking objectsaround terminal device 3306 in stage 3604. Sensor 3514 may then performsensing around terminal device 3306 to detect any blocking objects. Invarious aspects, sensor 3514 may be an infrared sensor, a capacitivesensor, a resistive sensor, an optical sensor, a piezoelectric sensor, acamera, a microphone, a radar sensor, or the like. Sensor 3514 may beconfigured to perform human object sensing depending on its sensor type.For example, the infrared sensor measures infrared light and may beconfigured to detect a human object based on a known IR signature, thecamera may be configured to detect a human object via image recognition,the capacitive sensor may be configured to detect a human object byobserving charge variations in a capacitor, and so forth. In someaspects, sensor 3514 may be a mmWave radar sensor, and may use anantenna array of antenna system 3502 to detect a human object (e.g., anantenna array-based radar sensor). This is further described below inFIGS. 37 and 38.

Sensor 3514 may be configured to sense directionally and may thereforeperform sensing in different sensor directions to determine whether anyblocking objects are located in that sensor direction (relative toterminal device 3306). FIGS. 33 and 34 show examples of sensordirections, e.g., sensor directions A-F. Sensor 3514 may determinewhether any blocking objects are detected and, if so, record the sensordirection of the blocking object. The sensor directions shown in FIGS.33 and 34 are exemplary. For example, while FIGS. 33 and 34 show thesensor directions as having coarser resolution than the antenna arrays'directional resolution (the resolution of the sectors), in otherexamples the sensor directions may have finer resolution than theantenna array's directional resolution. In some aspects, the sensordirections may have an angular resolution of, for example, one degree orless, and may therefore be able to detect the directional angle of ablocking object with resolution of a degree or less. In some aspects,sensor 3514 may determine a range of angles as the sensor direction of ablocking object, where the range of angles specifies the angular rangethat the blocking object is blocking. For example, sensor 3514 maydetermine a range of angles from 30-50 degrees for a blocking objectthat sensor 3514 detects as blocking the range of angles from 30-50degrees around terminal device 3306.

Sensor 3514 may also determine the distance of the blocking object fromterminal device 3306. Using the example of FIG. 33, sensor 3514 maydetermine that blocking object 3312 is located at sensor direction Brelative to terminal device 3306. Sensor 3514 may then determine thedistance of blocking object 3312 according to the sensor type of sensor3514 (e.g., an infrared sensor, a capacitive sensor, a resistive sensor,an optical sensor, a piezoelectric sensor, a camera, a microphone, aradar sensor). For example, depending on the strength of the detection,sensor 3514 may determine how proximate blocking object 3312 is fromterminal device 3306.

Sensor 3514 may then, in stage 3606, classify the blocking objects ashuman or non-human. In some aspects, sensor 3514 may be configured todetermine whether a blocking object has properties of living tissue and,if so, may classify the blocking object as human (e.g., sensor 3514 maynot specifically classify the blocking object as human living tissue vs.animal living tissue). For example, a capacitive or resistive sensor maydistinguish between human and non-human blocking objects based on theconductive or resistive properties of a blocking object (where livingtissue has a different conductivity than non-living tissue). An opticalsensor or camera may distinguish between human and non-human blockingobjects with image recognition, where the shapes of human bodies andhuman body parts are distinct from non-human objects. An infrared sensormay distinguish between human and non-human blocking objects based onthe infrared radiation, heat signature, and/or movement of humans, whichis distinct from that of non-human objects. A microphone may distinguishbetween human and non-human blocking objects based on the distinctsounds (e.g., human vocal speech or breathing) made by humans. A radarsensor (including, for example, the mmWave radar sensor described below)may distinguish between human and non-human objects based on Dopplereffects, radio wave reflectivity, or the frequency-dependent radioreflectivity. This is further described below for the mmWave radarsensor.

Based on the object sensing and classification, sensor 3514 may generatea list of blocking objects in stage 3608. In one example, the list ofblocking objects may include, for each blocking object: the sensordirection, the distance, and, a human object indicator (indicatingwhether the blocking object is human or non-human). In some cases, thelist may also include the velocity of the blocking objects (detected bysensor 3514) and/or the size of the blocking objects (detected by sensor3514). Sensor 3514 may then provide the list of blocking objects tocontroller 3512.

As previously explained, terminal device 3306 may be configured to abideby human exposure power limits, such as MPE or SAR restrictions. Theserestrictions limit the amount of RF energy that terminal device 3306'stransmissions can deliver to a human body. Accordingly, if terminaldevice 3306 is transmitting on a sector of antenna system 3502 thatpoints at a human object, terminal device 3306 may need to reduce itstransmit power to comply with the human exposure power limits. As shownin FIG. 36, controller 3512 may therefore estimate the maximum allowabletransmit power in sectors with human objects in stage 3610. For example,the list of blocking objects may indicate that certain sensor directionscontain human objects, and that the human objects are located a specificdistance from terminal device 3306. Controller 3512 may then identifythe sectors of antenna system 3502 that map to these human-blockedsensor directions (e.g., which sectors overlap directionally with thehuman-blocked sensor directions). Using FIG. 34 as an example, the listof blocking objects may indicate that sensor direction A is blocked by ahuman object (at a specific distance from terminal device 3306).Controller 3512 may then compare sensor direction A (e.g., the angularrange that defines sensor direction A) with the sectors of antennasystem 3502. Similar to that described for antenna array 3308 in FIG.34, antenna system 3502 may support a plurality of sectors, wherecontroller 3512 can configure antenna system 3502 to transmit or receiveon any of the sectors using phased array techniques. Because each ofantenna system 3502's sectors are known in advance, controller 3512 maycompare the angular range that defines sensor direction A (the sensordirection that is blocked by a human object) with the angular rangesthat define the sectors of antenna system 3502.

Based on this comparison, controller 3512 may identify the sectors thatare also blocked by human objects. Controller 3512 may then estimate themaximum allowable transmit power for these sectors. For example,controller 3512 may use a human exposure power limit (e.g., for an MPEor SAR restriction) and, based on the distance between terminal device3306 and the human object, determine a maximum allowable transmit powerthat could be used for a given sector without exceeding the humanexposure power limit. If the distance of the human object is farther,the maximum allowable transmit power may be larger; conversely, ifdistance is smaller, the maximum allowable transmit power may besmaller. In some aspects, controller 3512 may estimate the maximumallowable transmit power based on the amount of directional overlapbetween the sector and the sensor direction of the human blockingobject. For example, the maximum allowable transmit power may beinversely proportional to the amount of directional overlap. In otherwords, more directional overlap may mean that the sector is steereddirectly towards the human blocking object, which means that the maximumallowable transmit power will be lower to still comply with the humanexposure power limit.

After estimating the maximum allowable transmit power for sectors withhuman objects, controller 3512 may, in stage 3612, select sectors tosweep during the beamsweeping. These sectors may be referred to ascandidate sectors, as they are the sectors that controller 3512 selectsto evaluate. Controller 3512 may perform this selection based ondifferent selection logic in different aspects. For example, in someaspects, controller 3512 may be configured to select sectors in stage3612 based on the level that they are blocked by a blocking object. Inone example, controller 3512 may use the list of blocking objects anddetermine which sectors are partially or fully blocked by a blockingobject (e.g., identify one or more blocked sectors, which may bepartially or fully blocked). For instance, controller 3512 may identifya first blocking object in the list of blocking objects and thenidentify the sensor directions that the blocking object occupies (e.g.,a single direction or an angular range that represents which angles theblocking object occupies). Controller 3512 may then compare the sensordirections to the angular ranges of each sector available to antennasystem 3502 and determine which sectors are blocked by the blockingobject (e.g., which sectors have angular ranges that fall in the sensordirections of the blocking object). Using FIG. 34 as an example,controller 3512 may determine that blocking object 3402 is located insensor direction A, and that sectors 1 to 3 have angular ranges thatoverlap with blocking object 3402. Sectors 4 to 7, however, have angularranges that do not overlap with blocking object 3402. Controller 3512may thus determine that sectors 1 to 3 are blocked but that sectors 4 to7 are not blocked. If sensor 3514 detected other blocking objects,controller 3512 may be configured to similarly determine which sectorsare blocked, and which are not, by those blocking objects. In someaspects, controller 3512 may be configured to select in stage 3612sectors that are not blocked and to omit sectors that are blocked.

In some aspects, controller 3512 may be configured to determine thelevel that sectors are blocked (e.g., the amount of the sector that isblocked) and to select sectors in stage 3612 based on that blockinglevel. For example, controller 3512 may compare, for a given blockingobject, the sensor directions to the angular ranges of the availablesectors. Controller 3512 may then, for the sectors that are blocked bythe blocking object, determine how much of the sectors are blocked, orin other words, the level that each sector is blocked. Controller 3512may determine this blocking level as, for example, a percentage. UsingFIG. 34 as an example, controller 3512 may compare the sensor directionsof blocking object 3402 to the angular ranges of sectors 1 to 7 (theavailable sectors) and determine that blocking object 3402 blockssectors 1 to 3. Controller 3512 may then determine how much of sectors 1to 3 are respectively blocked by blocking object 3402. For example, bycomparing the angular ranges of sectors 2 and 3 to the sensor directionsof blocking object 3402, controller 3512 may determine that blockingobject 3402 fully blocks sectors 2 and 3 (e.g., the sensor directions ofblocking object 3402 has an angular range that fully overlaps with therespective angular ranges of sectors 2 and 3). In other words, blockingobject 3402 blocks 100% of both sectors 2 and 3. On the other hand,controller 3512 may determine that blocking object 3402 only partiallyblocks sector 1. For example, by comparing the angular range of sector 1with the sensor directions of blocking object 3402, controller 3512 mayestimate that blocking object 3402 blocks a certain amount of sector 1,such as 33% of sector 1's angular range. Controller 3512 may alsodetermine that blocking object 3402 does not block any of sectors 4-7,e.g., 0% of their angular ranges.

Using this procedure, controller 3512 may determine how much of eachsector is blocked by a blocking object, or in other words, may determinea blocking level for each sector. If a sector is blocked by multipleblocking objects, controller 3512 may determine the blocking level forthat sector by adding up the total angular range of that sector that isblocked by any blocking object. Controller 3512 may then select sectorsin stage 3612 based on the blocking levels of the sectors. For example,controller 3512 may use a predefined blocking level threshold, and mayselect only sectors that have a blocking level less than the predefinedblocking threshold in stage 3612 (e.g., only sectors that are blocked byless than a predefined amount). Continuing with the example based onFIG. 34, controller 3512 may use 25% as the predefined blockingthreshold, and may select only sectors that have blocking levels lessthan 25% in stage 3612. Controller 3512 may therefore select sectors 1and 4 to 7 but may omit sectors 2 and 3. This predefined blockingthreshold of 25% is exemplary and can be scaled to any other value.

In some aspects, controller 3512 may also consider the distance of theblocking object from terminal device 3306 when selecting sectors, suchas where controller 3512 selects sectors based on both blocking leveland distance. In one example, controller 3512 may set a blockingthreshold based on the blocking object's distance and then selectsectors based on which sectors have blocking levels less than theblocking threshold. For instance, controller 3512 may set the blockingthreshold to 50% (e.g., a first blocking threshold) when the blockingobject is a first distance and may set the blocking threshold to 33%(e.g., a second blocking threshold less than the first blockingthreshold) when the blocking object is a second distance that is lessthan the first distance. In other words, controller 3512 may set theblocking threshold to a higher value when the blocking object is fartheraway (thus allowing selection of sectors with more blocking), and to alower value when the blocking object is closer (thus only selectingsectors with little blocking). Controller 3512 may then select sectorsin stage 3612 that have blocking levels less than the blockingthreshold. This means that when the blocking object is farther away,controller 3512 may select sectors that are blocked to a greater degree.This is because the blocking may not be as severe when the blockingobject is farther away, so even sectors that are significantly blockedmay still yield high link quality with the network access node.Conversely, when the blocking object is very close sectors that areblocked even a small degree may not be able to support sufficient linkquality with the network access node.

In some aspects, controller 3512 may select sectors in stage 3612 basedon the maximum allowable transmit powers calculated in stage 3610 forsectors blocked by human objects. As explained above, these maximumallowable transmit powers may be higher for human objects that arefarther away and lower for human objects that are closer; additionally,if terminal device 3306 transmits on one of these sectors, terminaldevice 3306 may need to transmit at or less than the maximum allowabletransmit power in order to comply with the human exposure power limits.Accordingly, in some aspects controller 3512 may select sectors in stage3612 based on a predefined allowable transmit power threshold, such aswhere controller 3512 only selects sectors with maximum allowabletransmit powers that are greater than the predefined allowable transmitpower threshold. Sectors that are not blocked by a human object (e.g.,not blocked at all, or blocked only by non-human objects) may not besubject to the same restrictions as those that are blocked by humanobjects; these sectors that are not blocked by a human object mattherefore have the same maximum allowable transmit power that is higherthan that of the sectors blocked by a human object. Accordingly, whenconsidering the predefined allowable transmit power threshold,controller 3512 may select sectors that are not blocked by a humanobject and sectors that are blocked by a human object but still have amaximum allowable transmit power greater than the predefined allowabletransmit power threshold. Since the remaining sectors will have lowmaximum allowable transmit powers, they may not be viable options forterminal device 3306 to use when communicating with network access node3302. Controller 3512 may therefore omit these sectors from the selectedsectors in stage 3612.

In some aspects, controller 3512 may select sectors to sweep in stage3612 by generating a weighted sector list in which each sector isassigned a priority. Controller 3512 may assign these priorities to thesectors based on various factors. For example, controller 3512 mayassign higher priorities to sectors that are less blocked by blockingobjects (low blocking level) and lower priorities to sectors that aremore blocked by blocking objects (high blocking level). In anotherexample, controller 3512 may assign higher priorities to sectors thatare blocked by non-human objects than the priorities assigned to sectorsblocked by human objects. In a further example for sectors blocked byhuman objects, controller 3512 may assign higher priorities to thesectors that have higher maximum allowable transmit power than thesectors with lower maximum allowable transmit power. In some aspects,controller 3512 may assign the priorities based on multiple of blockinglevel, human vs. non-human blocking, or maximum allowable transmitpower. The pairs of sectors and priorities may form the weighted sectorlist. Controller 3512 may then select the sectors in stage 3612 based onthe weighted sector list. For example, controller 3512 may select apredefined number of sectors with the highest priorities in the weightedsector list.

In some aspects, controller 3512 may select the sectors in stage 3612based on multiple antenna arrays of terminal device 3306. For example,antenna system 3502 may include multiple antenna arrays, such as antennaarrays 3308 and 3310 shown in FIG. 33. Because antenna arrays 3308 and3310 are positioned in different locations around the housing ofterminal device 3306, their respective sectors may point in differentdirections. Accordingly, in some cases one of the antenna arrays may beblocked while the other is not. FIG. 33 shows an example of this. Insome aspects, controller 3512 may be configured to determine that thesectors of a first antenna array (of a plurality of antenna arrays ofterminal device 3306) are blocked by a blocking object while the sectorsof a second antenna array are not blocked. Controller 3512 may thereforenot select any of the first antenna array's sectors as sectors in stage3612, and may instead select the sectors in stage 3612 from the secondantenna array.

To recap stage 3612, controller 3512 may select from the available setof sectors in to identify a plurality of selected sectors. Controller3512 may perform this selection based on any factor or criteriadescribed above. After obtaining the selected sectors, controller 3512may perform beamsweeping on the selected sectors in stage 3614. Forexample, controller 3512 may transmit or receive signals with antennasystem 3502 on the selected sectors to measure the link quality for eachsector. This can follow any type of beamsweeping procedure. For example,the WiGig standard specifies a sector level sweep (SLS) beamsweepingpattern where an initiator device performs a sector sweep (ISS) to trainits transmitter (known as ISS TXSS) and/or receiver (ISS RXSS), andwhere a responder device performs a sector sweep (RSS) to train itstransmitter (RSS TXSS) and/or receiver (RSS RXSS). In these sectorsweeps, network access node 3302 or terminal device 3306 maysequentially step through its sectors and measure the link quality whilethe other device transmits or receives a reference signal (e.g., asector sweep frame (SSW)). Network access node 3302 or terminal device3306 may then identify which sectors provide the best link quality andselect a sector to use for transmission or reception with each other.

In standard beamsweeping, terminal device 3306 may test each of a set ofsectors of antenna system 3502 (e.g., each sector of each antenna array,including where antenna system 3502 has multiple antenna arrays like inFIG. 33). To avoid such a long and power-consuming procedure, controller3512 may instead perform the beamsweeping on only the selected sectorsin stage 3614. For instance, in an exemplary receive beamsweepingprocedure where network access node 3302 transmits reference signals(e.g., with a quasi-omni directional antenna pattern at antenna array3502) to terminal device 3306 and terminal device measures the linkquality of its sectors, controller 3512 may control antenna system 3502to only receive with the selected sectors. Digital receiver 3508 maytherefore only measure the link quality on the selected sectors. Sincedigital receiver 3508 measures only some of the overall set of sectors,this can save power and time. In some aspects, terminal device 3302 andnetwork access node 3306 may agree in advance which sectors to test, andmay shorten the beamsweeping procedure so only the selected sectors aretested. In other aspects, terminal device 3302 and network access node3306 may not agree in advance which sectors to test, and may instead beconfigured to perform a beamsweeping procedure of predefined duration(e.g., a duration long enough to test each sector). In those cases,controller 3512 may control digital receiver 3508 to measure the linkquality for only the selected sectors, and may control antenna system3502 to receive only for those selected sectors. Controller 3512 maytherefore skip measuring the link quality for the non-selected sectors.Although the beamsweeping procedure may still take the predefinedduration of time, terminal device 3302 may save power by not testingeach of the available sectors.

In an exemplary transmit beamsweeping procedure, terminal device 3306may transmit reference signals on each sector and network access node3302 may measure the link quality for each sector (e.g., with aquasi-omni directional antenna pattern at antenna array 3502). Networkaccess node 3302 may select the sector (or sectors) with the best linkquality and send feedback to controller 3512 that identifies that sector(or sectors). In stage 3614 for this case, controller 3512 may controlantenna system 3502 and digital transmitter 3510 to only transmit thereference signals with the selected sectors. If terminal device 3306 andnetwork access node 3302 can agree in advance on which sectors to test,controller 3512 may configure the beamsweeping procedure to only testthe selected sectors. Otherwise, if terminal device 3306 and networkaccess node 3302 are configured to perform a beamsweeping procedure ofpredefined duration, controller 3512 may control antenna system 3502 anddigital transmitter 3510 to only transmit the reference signals with theselected sectors. Terminal device 3306 may not transmit any referencesignal during time slots assigned for the non-selected sectors, andnetwork access node 3302 may measure very poor link quality for thosesectors. As a result, network access node 3302 may not select to use anyof the non-selected sectors for beamforming.

After the beamsweeping is finished, controller 3512 may select a targetsector for transmitting and/or receiving with network access node 3302in stage 3618. Because controller 3512 only performed beamsweeping onthe selected sectors, controller 3512 may select the target sector fromthe selected sectors. For receive beamsweeping, controller 3512 mayselect the target sector based on the link qualities for each selectedsector. For example, controller 3512 may identify which selected sectorhad the highest link quality (as measured by digital receiver 3508) andmay select that sector as the target sector. For transmit beamforming,network access node 3302 may send feedback to controller 3512 thatidentifies one or more sectors that had the highest link qualities.Controller 3512 may then select the target sector based on thisfeedback, such as where controller 3512 selects the target sector as theselected sector for which network access node 3302 reported the highestlink quality.

In some aspects, controller 3512 may select the target sector in stage3618 based on the maximum allowable transmit power. For instance,because sectors with human objects may be subject to transmit powerrestrictions, controller 3512 may consider how much its transmit powerwill be restricted if it transmits with one of those sectors. In oneexample, controller 3512 may scale down link quality measurements fromthe beamsweeping based on the maximum allowable transmit power, and maythen select the target sector based on the scaled link qualitymeasurements. Because sectors that are not blocked by a human object maynot be subject to the human exposure power limits, controller 3512 mayscale down link quality measurements for human-blocked sectors but maynot scale down link quality measurements for unblocked sectors. This mayweight selection of the target sector to unblocked sectors; however, ifthere is a human-blocked sector with very high link quality, it maystill have the highest scaled link quality measurement. In some aspects,controller 3512 may scale down the link quality measurements (e.g., allof the link quality measurements, or a subset of the highest linkquality measurements) based on the maximum allowable transmit power, andmay then select the target sector as the sector with the highest scaledlink quality measurement.

In some aspects, controller 3512 may alternatively identify the sectorwith the highest link quality measurement, and then determine whetherthis sector is pointed at a human object (e.g., per the human objectindicator in the list of blocking objects). If the sector with thehighest link quality measurement is not pointed towards a human object,controller 3512 may select that sector as the target sector in stage3618. If the sector with the highest link quality measurement is pointedtowards a human object, controller 3512 may scale down the link qualitymeasurements based on the maximum allowable transmit powers (e.g., scaledown all of the link quality measurements, or scale down only a subsetof the highest link quality measurements). After scaling down the linkquality measurements, controller 3512 may select the sector with thehighest scaled link quality measurement as the target sector in stage3614.

Once controller 3512 selects the target sector, controller 3512 maycontrol terminal device 3306 to transmit or receive with the targetsector. For example, controller 3512 may perform RF or digitalbeamforming based on a beamforming weight vector for the target sector.Antenna array 3502 may therefore transmit or receive with the targetsector. As described above, this may focus terminal device 3306'stransmission or reception in the direction of the target sector, whichcan in turn provide beam gain for the radio link with network accessnode 3302.

In some aspects, controller 3512 may refine the target sector in a beamrefinement procedure, such as WiGig's beam refinement protocol (BRP). Ina beam refinement procedure, terminal device 3306 and network accessnode 3302 may selectively narrow or focus the antenna beams for theradio link, such as by adapting the beamforming weight vector to find anantenna beam that further increases the beam gain of the radio link.After refining the target sector in such a procedure, controller 3512may control terminal device 3306 to use the refined target sector totransmit or receive with network access node 3302.

Various aspects above detailed examples where terminal device 3306 has asensor (e.g., sensor 3514) dedicated to object sensing. In otheraspects, terminal device 3306 may use antenna system 3502 as a radarsensor, such as where terminal device 3306 uses antenna system 3502 as aradar device that transmits signals and detects nearby objects based onthe resulting reflected signals.

FIG. 37 shows an exemplary internal configuration of terminal device3306 according to some aspects where terminal device 3306 uses antennasystem 3502 as part of a radar sensor. As shown in FIG. 37, terminaldevice 3306 may, like in FIG. 33, include antenna system 3502, RFtransceiver 3504 and baseband modem 3506 that includes digital receiver3508, digital transmitter 3510, and controller 3512. Terminal device3306 may also include radar controller 3516, which may be connected tothe transmit and receive paths of RF transceiver 3504. Radar controller3516 may form the radar sensor along with antenna system 3502. Radarcontroller 3516 may be configured to transmit radio signals via RFtransceiver 3504 and antenna system 3502 and to receive the resultingreflected radio signals after the transmitted radio signals reflect backoff objects. Radar controller 3516 may then process these reflectedsignals to sense the objected around terminal device 3306. Accordingly,instead of using a separate sensor (such as sensor 3514 as described inFIG. 35) to detect blocking objects, terminal device 3306 may useantenna system 3502 and radar controller 3516 as a radar sensor todetect blocking objects.

FIG. 38 shows an exemplary diagram of antenna system 3502, RFtransceiver 3504, and radar controller 3516 according to some aspects.These components may form the radar sensor of terminal device 3306. Asshown in FIG. 38, antenna system 3502 may include antenna array 3502 a,switch 3502 b, transmit PA bank 3502 c, transmit phase shifter array3502 d, transmit splitter 15023, transmit RF amplifier 3504 a, receiveLNA bank 3502 f, receive phase shifter array 3502 g, and receivecombiner 3502 h. RF transceiver 3504 may include transmit RF amplifier3504 a and receive RF amplifier 3504 b. Radar controller 3516 mayinclude transmit RF amplifier 3516 a, local oscillator 3516 b, chirpgenerator 3516 c, receive RF amplifier 3516 d, six-port detector 3516 e,power detector bank 3516 f, ADCs 3516 g, and DSP 3516 h.

The basic operation is as follows. Radar controller 3516 controls RFtransceiver 3504 and antenna system 3502 to radiate a signal fromantenna array 3502. That signal radiates outward in space from terminaldevice 3306 until it hits one or more blocking objects around terminaldevice 3306. Once the radiated signal hits a blocking object, it isscattered. Some of the radiation enters or propagates through theblocking object and some of the radiation is reflected back by theblocking object. The blocking object's characteristics determine howmuch radiated energy is absorbed by or propagates through the object andhow much radiated energy is reflected back. These object characteristicsinclude the blocking object's size, shape, and the type of material itis made of

The signal that the blocking object reflects back is called thereflected signal. Because the blocking object's characteristics willinfluence the reflected signal in specific ways, terminal device 3306can receive the reflected signal with antenna system 3502 and processthe reflected signal with radar controller 3514 to extract informationfrom the reflected signal. This information can include the reflectedpower, range, Doppler, and the like. Based on this information, radarcontroller 3514 may determine the distance, sensor direction, andwhether the blocking object is a human object or not. Radar controller3514 may provide this information to controller 3512, which may use theinformation to select sectors for beamsweeping and to select a targetsector for transmitting and receiving.

This operation will now be described in detail, starting first with thetransmit direction and then continuing to the receive direction. In thetransmit direction, local oscillator 3516 b may generate a localoscillation signal (e.g., using a crystal oscillator). In some aspects,local oscillator 3516 b may be a voltage-controlled oscillator (VCO)that generates a frequency tone based on the voltage control provided bychirp generator 3516 c. Chirp generator 3516 c may generate discretechirps which, when used to control local oscillator 3516 c, produces acontinuous wave (CW) signal in multiple frequencies that are eachgenerated for a short period of time. Then, as shown in FIG. 38,transmit RF amplifier 3516 a and transmit RF amplifier 3504 a mayamplify the discrete chirp signal. Transmit splitter 3502 e may splitthis transmit signal (the discrete chirp signal) into multiple paths andprovide each path to one of the phase shifters in phase shifter array3502 d. These phase shifters, which terminal device 3302 uses forphased-array RF beamforming, may then apply respective phase shifts(e.g., according to a beamforming weight vector) and provide theresulting phase-shifted signals to transmit PA bank 3502. The transmitPAs in transmit PA bank 3502 c may amplify the phase-shifted signals andprovide the amplified signals to switch 3502 b. Switch 3502 b mayconnect each transmit PA in transmit PA bank 3502 c to one of theantennas in antenna array 3502 a, and may be configured to switch theantennas of antenna array 3502 a between transmitting and receiving.Switch 3502 b may therefore switch antenna array 3502 a to transmit, andantenna array 3502 a may wirelessly transmit the discrete chirp signal.In this exemplary configuration, antenna system 3502 may re-use the sameantennas for transmission and reception. In other exemplaryconfigurations, antenna system 3502 may include separate sets oftransmit antennas and receive antennas (and, e.g., no switch 3502 b).

This radiated signal may then radiate out from antenna array 3502 andhit one or more blocking objects. These blocking objects may reflect theradiated signal back towards terminal device 3306 as a reflected signal.As discussed above, the blocking objects' size, shape, and material typemay influence the properties of the reflected signal. Antenna array 3502a may then receive the reflected signal, and switch 3502 b may switch toreceive and provide the received reflected signal to receive LNA bank3502 f (e.g., the output of each antenna element in antenna array 3502 ato a respective LNA in LNA bank 3502 f). LNA bank 3502 f may performlow-noise amplification and provide the resulting amplified signals toreceive phase shifter array 3502 g. Like transmit phase shifter array3502 d, receive phase shifter array 3502 g may perform phased-array RFbeamforming by applying respective phase shifts (e.g., according to abeamforming weight vector) and providing the resulting phase-shiftedsignals to receive combiner 3502 h. Receive combiner 3502 h may combinethe phase-shifted signals (e.g., by summing) and provide the combinedsignal to receive RF amplifier 3504 b.

Radar controller 3516 may then process the reflected signal (thecombined signal) to sense blocking objects near terminal device 3306. Asshown in FIG. 38, receive RF amplifier 3516 d may perform low-noiseamplification and provide this signal to six-port detector 3516 e.Six-port detector 3516 e may also receive the output signal from localoscillator 3516 b, which is the transmit signal. Using these two inputs,six-port detector 3516 e may add the transmit signal with the reflectedsignal at four relative phase offsets (e.g., 0, 90, 180, and 270degrees; in other aspects, six-port detector 3516 e can use more orfewer phase offsets). Six-port detector 3516 e may then provide thosephase isolation signals as its outputs. Depending on the phasedifference between the transmit signal and the reflected signal, theoutputs will constructively or destructively add by varying amounts.Power detector bank 3516 f may then, with each of its power detectors,perform power detection on a respective output to determine the phasedifference. ADCs 3516 g may then perform analog to digital conversion todigitize the phase differences and provide the phase differences to DSP3516 h. In the example shown in FIG. 38, ADCs 3516 g are twodifferential ADCs, one for in-phase and one for quadrature. In otherexamples, ADCs 3516 g may have four ADCs, each of which performs ADC onan output of six-port detector 3516 e.

DSP 3516 h may then evaluate the phase differences to determine therange of the reflected signal, or in other words, the distance fromantenna array 3502 a at which a blocking object is located. For example,the radiated transmit signal propagates wirelessly through free spacebefore reflecting off a blocking object and returning back to terminaldevice 3306. The reflected signal will therefore have a different phasefrom the transmit signal produced by local oscillator 3516 b, where thephase difference indicates the distance that the reflected signaltraveled. The phase difference therefore also indicates how far away theblocking object is. DSP 3516 h may also measure the strength of thereflected signal and, based on the strength, may determine the degree towhich a blocking object is present. In various aspects, DSP 3516 h mayuse any of the techniques described in US Patent Application PublicationUS 2018/0180713 A1 to determine the distance and other characteristicsof the blocking object.

In some aspects, terminal device 3306 may use radar controller 3516 andantenna system 3502 as a sensor to execute flow chart 3600 describedabove in FIG. 36. Accordingly, instead of using sensor 3514 to detectblocking objects around terminal device 3306 in stage 3604, radarcontroller 3516 may detect blocking objects by using antenna system 3502to radiate a transmit signal and to receive the reflected signal and bythen processing the reflected signal to determine the distance anddirection of blocking objects. In some aspects, radar controller 3516may be configured to steer antenna array 3502 a's beam in differentdirections to perform object sensing in different directions. Forexample, radar controller 3516 may be configured to control transmitphase shifter array 3502 d and receive phase shifter array 3502 g tosteer the transmit and receive antenna beams in different sensordirections. Radar controller 3516 may then detect blocking objects inthose sensor directions, such as in the same manner that sensor 3514detected blocking objects in sensor directions described above.

In some aspects, radar controller 3516 may also be configured todetermine whether a blocking object is a human object, and may thereforeclassify blocking objects as human or non-human in stage 3606 of flowchart 3600. For example, in some aspects radar controller 3516 may beconfigured to identify human object movements and tremor based on thereflected signal's Doppler and micro-Doppler effects. Specifically, whena human object is placed in front of antenna system 3502, natural bodytremors will cause unique Doppler effects in the reflected signal, andthe reflected signal will have phase and frequency variations. Radarcontroller 3516 may therefore detect the Doppler and micro-Dopplereffects in the reflected signal and, based thereon, may determine thatthe blocking object is a human object.

In some aspects, radar controller 3516 may be configured to correlatethe blocking object's distance (e.g., determined by DSP 3516 h) with itsreflectivity and to distinguish between human and non-human blockingobjects based on the correlation. Specifically, because each object hasa reflection coefficient, radar controller 3516 may measure the blockingobject's reflectivity based on the reflected signal and correlate thatreflectivity with the blocking object's distance. Radar controller 3516may then, based on offline characterization, classify what material theblocking object is made of and determine whether the blocking object ishuman.

In some aspects, radar controller 3516 may measure the reflectivity ofan object across a wide frequency range and then compare the resultingfrequency signature with the expected response of the reflectivity of ahuman object (which may be pre-characterized offline). Since eachmaterial, including human tissue, has its own frequency response andreflectivity, radar sensor 3516 can compare the reflected signal'sfrequency signature with the pre-characterized properties of humantissue and distinguish between human and non-human objects.

In some aspects, radar controller 3516 may combine multiple of thesetechniques to classify blocking objects as human or non-human in stage3606.

After classifying blocking objects as human or non-human in stage 3606,terminal device 3306 may perform the rest of flow chart 3600 asdescribed above for FIG. 36. Accordingly, terminal device 3306 may useradar controller 3516 and antenna system 3502 in place of sensor 3514(e.g., may use radar controller 3516 and antenna system 3502 as a radarsensor). This may have several advantages. For example, because terminaldevice 3306 uses the same antenna array for both object sensing andradio transmission, the sensor beams may be spatially correlated withthe antenna beams. Compared to other cases where the sensor is placed ata different location from the antenna array (or is facing a differentdirection from the antenna array), aspects using antenna system 3502 forboth sensing and radio transmission may be more accurate in determiningwhich antenna beams are blocked. Aspects using antenna system 3502 forboth sensing and radio transmission may therefore be better able toselect the best sectors and to comply with human exposure power limits.

To summarize, these aspects that select sectors to sweep based onblocking objects may provide several advantages. For example, becauseterminal device 3306 only sweeps some of the available sectors, the timeit takes to connect to the network (initial network access time) may bereduced. Additionally, when the radio link with network access node 3302is lost, terminal device 3306 may be able to reconnect and recover in ashorter amount of time. These aspects can also save power. Becauseterminal device 3306 sweeps only some of the sectors, terminal device3306 may consume less battery power and may increase its battery life.Furthermore, these aspects may save radio resources. For instance, whenterminal device 3306 and network access node 3302 can agree in advanceto only sweep some of the sectors, the beamsweeping may take less timeand therefore occupy less radio resources. This leaves more radioresources to use for data communication, which in turn increases networkdata bandwidth and throughput. Lastly, these aspects may be more capableof abiding by human exposure power regulations. Because terminal device3306 considers the presence of human blocking objects and thecorresponding maximum allowable transmit powers, terminal device 3306may avoid delivering excessive RF energy to human objects.

FIG. 39 shows exemplary method 3900 according to some aspects. As shownin FIG. 39, method 3900 includes detecting, with a sensor, one or moreobjects around the communication device (3902), identifying one or moreblocked sectors of an antenna array that are blocked by the one or moreobjects (3904), selecting, based on the one or more blocked sectors, oneor more candidate sectors of the antenna array to evaluate (3906), anddetermining radio link qualities of the one or more candidate sectors(3908).

FIG. 40 shows exemplary method 4000 according to some aspects. As shownin FIG. 40, method 4000 includes detecting, with a sensor, one or morehuman objects around the communication device (4002), identifying one ormore human-blocked sectors of an antenna array that are blocked by theone or more human objects (4004), estimating a maximum allowabletransmit power for the one or more human-blocked sectors (4006),selecting one or more candidate sectors of the antenna array to evaluatebased on maximum allowable transmit powers (4008), and determining radiolink qualities of the one or more candidate sectors (4010).

While the above descriptions and connected figures may depict electronicdevice components as separate elements, skilled persons will appreciatethe various possibilities to combine or integrate discrete elements intoa single element. Such may include combining two or more circuits forform a single circuit, mounting two or more circuits onto a common chipor chassis to form an integrated element, executing discrete softwarecomponents on a common processor core, etc. Conversely, skilled personswill recognize the possibility to separate a single element into two ormore discrete elements, such as splitting a single circuit into two ormore separate circuits, separating a chip or chassis into discreteelements originally provided thereon, separating a software componentinto two or more sections and executing each on a separate processorcore, etc.

Any of the radio links described herein may operate according to any oneor more of the following radio communication technologies and/orstandards including but not limited to: a Global System for MobileCommunications (GSM) radio communication technology, a General PacketRadio Service (GPRS) radio communication technology, an Enhanced DataRates for GSM Evolution (EDGE) radio communication technology, and/or aThird Generation Partnership Project (3GPP) radio communicationtechnology, for example Universal Mobile Telecommunications System(UMTS), Freedom of Multimedia Access (FOMA), 3GPP Long Term Evolution(LTE), 3GPP Long Term Evolution Advanced (LTE Advanced), Code divisionmultiple access 2000 (CDMA2000), Cellular Digital Packet Data (CDPD),Mobitex, Third Generation (3G), Circuit Switched Data (CSD), High-SpeedCircuit-Switched Data (HSCSD), Universal Mobile TelecommunicationsSystem (Third Generation) (UMTS (3G)), Wideband Code Division MultipleAccess (Universal Mobile Telecommunications System) (W-CDMA (UMTS)),High Speed Packet Access (HSPA), High-Speed Downlink Packet Access(HSDPA), High-Speed Uplink Packet Access (HSUPA), High Speed PacketAccess Plus (HSPA+), Universal Mobile TelecommunicationsSystem-Time-Division Duplex (UMTS-TDD), Time Division-Code DivisionMultiple Access (TD-CDMA), Time Division-Synchronous Code DivisionMultiple Access (TD-CDMA), 3rd Generation Partnership Project Release 8(Pre-4th Generation) (3GPP Rel. 8 (Pre-4G)), 3GPP Rel. 9 (3rd GenerationPartnership Project Release 9), 3GPP Rel. 10 (3rd Generation PartnershipProject Release 10), 3GPP Rel. 11 (3rd Generation Partnership ProjectRelease 11), 3GPP Rel. 12 (3rd Generation Partnership Project Release12), 3GPP Rel. 13 (3rd Generation Partnership Project Release 13), 3GPPRel. 14 (3rd Generation Partnership Project Release 14), 3GPP Rel. 15(3rd Generation Partnership Project Release 15), 3GPP Rel. 16 (3rdGeneration Partnership Project Release 16), 3GPP Rel. 17 (3rd GenerationPartnership Project Release 17) and subsequent Releases (such as Rel.18, Rel. 19, etc.), 3GPP 5G, 3GPP LTE Extra, LTE-Advanced Pro, LTELicensed-Assisted Access (LAA), MuLTEfire, UMTS Terrestrial Radio Access(UTRA), Evolved UMTS Terrestrial Radio Access (E-UTRA), Long TermEvolution Advanced (4th Generation) (LTE Advanced (4G)), cdmaOne (2G),Code division multiple access 2000 (Third generation) (CDMA2000 (3G)),Evolution-Data Optimized or Evolution-Data Only (EV-DO), Advanced MobilePhone System (1st Generation) (AMPS (1G)), Total Access CommunicationSystem/Extended Total Access Communication System (TACS/ETACS), DigitalAMPS (2nd Generation) (D-AMPS (2G)), Push-to-talk (PTT), MobileTelephone System (MTS), Improved Mobile Telephone System (IMTS),Advanced Mobile Telephone System (AMTS), OLT (Norwegian for OffentligLandmobil Telefoni, Public Land Mobile Telephony), MTD (Swedishabbreviation for Mobiltelefonisystem D, or Mobile telephony system D),Public Automated Land Mobile (Autotel/PALM), ARP (Finnish forAutoradiopuhelin, “car radio phone”), NMT (Nordic Mobile Telephony),High capacity version of NTT (Nippon Telegraph and Telephone) (Hicap),Cellular Digital Packet Data (CDPD), Mobitex, DataTAC, IntegratedDigital Enhanced Network (iDEN), Personal Digital Cellular (PDC),Circuit Switched Data (CSD), Personal Handy-phone System (PHS), WidebandIntegrated Digital Enhanced Network (WiDEN), iBurst, Unlicensed MobileAccess (UMA), also referred to as also referred to as 3GPP GenericAccess Network, or GAN standard), Zigbee, Bluetooth(r), Wireless GigabitAlliance (WiGig) standard, mmWave standards in general (wireless systemsoperating at 10-300 GHz and above such as WiGig, IEEE 802.11ad, IEEE802.11ay, etc.), technologies operating above 300 GHz and THz bands,(3GPP/LTE based or IEEE 802.11p and other) Vehicle-to-Vehicle (V2V) andVehicle-to-X (V2X) and Vehicle-to-Infrastructure (V2I) andInfrastructure-to-Vehicle (I2V) communication technologies, 3GPPcellular V2X, DSRC (Dedicated Short Range Communications) communicationsystems such as Intelligent-Transport-Systems and others (typicallyoperating in 5850 MHz to 5925 MHz or above (typically up to 5935 MHzfollowing change proposals in CEPT Report 71)), the European ITS-G5system (i.e. the European flavor of IEEE 802.11p based DSRC, includingITS-G5A (i.e., Operation of ITS-G5 in European ITS frequency bandsdedicated to ITS for safety re-lated applications in the frequency range5,875 GHz to 5,905 GHz), ITS-G5B (i.e., Operation in European ITSfrequency bands dedicated to ITS non-safety applications in thefrequency range 5,855 GHz to 5,875 GHz), ITS-G5C (i.e., Operation of ITSapplications in the frequency range 5,470 GHz to 5,725 GHz)), DSRC inJapan in the 700 MHz band (including 715 MHz to 725 MHz) etc.

Aspects described herein can be used in the context of any spectrummanagement scheme including dedicated licensed spectrum, unlicensedspectrum, (licensed) shared spectrum (such as LSA=Licensed Shared Accessin 2.3-2.4 GHz, 3.4-3.6 GHz, 3.6-3.8 GHz and further frequencies andSAS=Spectrum Access System/CBRS=Citizen Broadband Radio System in3.55-3.7 GHz and further frequencies). Applicable spectrum bands includeIMT (International Mobile Telecommunications) spectrum as well as othertypes of spectrum/bands, such as bands with national allocation(including 450-470 MHz, 902-928 MHz (allocated for example in US (FCCPart 15)), 863-868.6 MHz (allocated for example in European Union (ETSIEN 300 220)), 915.9-929.7 MHz (allocated for example in Japan),917-923.5 MHz (allocated for example in South Korea), 755-779 MHz and779-787 MHz (allocated for example in China), 790-960 MHz, 1710-2025MHz, 2110-2200 MHz, 2300-2400 MHz, 2.4-2.4835 GHz (an ISM band withglobal availability, often used by Wi-Fi technology family (11b/g/n/ax)and also by Bluetooth), 2500-2690 MHz, 698-790 MHz, 610-790 MHz,3400-3600 MHz, 3400-3800 MHz, 3.55-3.7 GHz (allocated for example in theUS for Citizen Broadband Radio Service), 5.15-5.25 GHz and 5.25-5.35 GHzand 5.47-5.725 GHz and 5.725-5.85 GHz bands (allocated for example inthe US (FCC part 15), consists four U-NII bands in total 500 MHzspectrum), 5.725-5.875 GHz (allocated for example in EU (ETSI EN 301893)), 5.47-5.65 GHz (allocated for example in South Korea, 5925-7125MHz and 5925-6425 MHz band (under consideration in US and EU,respectively; next generation Wi-Fi system is expected to include the 6GHz spectrum as operating band but, as of December 2017, Wi-Fi system isnot yet allowed in this band; regulation is expected to be finished in2019-2020 time frame), IMT-advanced spectrum, IMT-2020 spectrum(expected to include 3600-3800 MHz, 3.5 GHz bands, 700 MHz bands, bandswithin the 24.25-86 GHz range, etc.), spectrum made available underFCC's “Spectrum Frontier” 5G initiative (including 27.5-28.35 GHz,29.1-29.25 GHz, 31-31.3 GHz, 37-38.6 GHz, 38.6-40 GHz, 42-42.5 GHz,57-64 GHz, 71-76 GHz, 81-86 GHz and 92-94 GHz, etc.), the ITS(Intelligent Transport Systems) band of 5.9 GHz (typically 5.85-5.925GHz) and 63-64 GHz, bands currently allocated to WiGig such as WiGigBand 1 (57.24-59.40 GHz), WiGig Band 2 (59.40-61.56 GHz) and WiGig Band3 (61.56-63.72 GHz) and WiGig Band 4 (63.72-65.88 GHz), 57-64/66 GHz(note: this band has near-global designation for Multi-Gigabit WirelessSystems (MGWS)/WiGig . In US (FCC part 15) allocates total 14 GHzspectrum, while EU (ETSI EN 302 567 and ETSI EN 301 217-2 for fixed P2P)allocates total 9 GHz spectrum), the 70.2 GHz-71 GHz band, any bandbetween 65.88 GHz and 71 GHz, bands currently allocated to automotiveradar applications such as 76-81 GHz, and future bands including 94-300GHz and above. Furthermore, the scheme can be used on a secondary basison bands such as the TV White Space bands (often below 790 MHz) where inparticular the 400 MHz and 700 MHz bands are promising candidates.Besides cellular applications, specific applications for verticalmarkets may be addressed such as PMSE (Program Making and SpecialEvents), medical, health, surgery, automotive, low-latency, drones, etc.applications.

Aspects described herein can also implement a hierarchical applicationof the scheme is possible, e.g. by introducing a hierarchicalprioritization of usage for different types of users (e.g.,low/medium/high priority, etc.), based on a prioritized access to thespectrum e.g. with highest priority to tier-1 users, followed by tier-2,then tier-3, etc. users, etc.

Aspects described herein can also be applied to different Single Carrieror OFDM flavors (CP-OFDM, SC-FDMA, SC-OFDM, filter bank-basedmulticarrier (FBMC), OFDMA, etc.) and in particular 3GPP NR (New Radio)by allocating the OFDM carrier data bit vectors to the correspondingsymbol resources. Some of the features in this disclosure are definedfor the network side, such as Access Points, eNodeBs, New Radio (NR) ornext generation Node Bs (gNodeB or gNB, which is typically used in thecontext of 3GPP fifth generation (5G) communication systems), etc.Still, in some aspects a User Equipment (UE) may take this role and actas an Access Points, eNodeBs, gNodeBs, etc. In other words, some or allfeatures defined herein for network equipment may be implemented by a UE(or terminal device).

It is appreciated that implementations of methods detailed herein aredemonstrative in nature, and are thus understood as capable of beingimplemented in a corresponding device. Likewise, it is appreciated thatimplementations of devices detailed herein are understood as capable ofbeing implemented as a corresponding method. It is thus understood thata device corresponding to a method detailed herein may include one ormore components configured to perform each aspect of the related method.

All acronyms defined in the above description additionally hold in allclaims included herein.

The following examples pertain to further aspects of this disclosure:

Example 1 is a method of performing radio communications at acommunication device, the method including transmitting data on a firstchannel with a first antenna beam and a first transmit power,determining an estimated radio frequency (RF) exposure power to a humanobject based on the first antenna beam and the first transmit power,determining whether the estimated RF exposure power is greater than anexposure power threshold, and if the estimated RF exposure power isgreater than the exposure power threshold, switching from the firstchannel to a second channel with narrower bandwidth and transmittingdata on the second channel with a second transmit power lower than thefirst transmit power.

In Example 2, the subject matter of Example 1 can optionally furtherinclude if the estimated RF exposure power is less than the exposurepower threshold, continuing to transmit data on the first channel withthe first antenna beam and the first transmit power.

In Example 3, the subject matter of Example 1 or 2 can optionallyinclude wherein switching from the first channel to the second channelincludes transmitting signaling to a network access node for channelswitching from the first channel to the second channel.

In Example 4, the subject matter of Example 3 can optionally includewherein transmitting the signaling to the network access node includestransmitting the signaling to the network access node on the secondchannel.

In Example 5, the subject matter of Example 3 or 4 can optionallyfurther include after transmitting the signaling to the network accessnode, receiving on the second channel a transmission grant fortransmitting data on the second channel.

In Example 6, the subject matter of any one of Examples 3 to 5 canoptionally include wherein the channel switch is a user equipment(UE)-triggered bandwidth part (BWP) switch procedure, and wherein thesecond channel is a default BWP and the first channel is a non-defaultBWP.

In Example 7, the subject matter of Example 6 can optionally furtherinclude if the estimated RF exposure power is greater than the exposurepower threshold, determining whether the default BWP has narrowerbandwidth than the non-default BWP, and triggering the BWP fallbackprocedure if the default BWP has narrower bandwidth than the non-defaultBWP.

In Example 8, the subject matter of Example 3 can optionally includewherein the channel switch is a user equipment (UE)-triggered bandwidthpart (BWP) switch procedure and wherein transmitting the signaling tothe network access node on the second channel includes transmitting arandom access transmission to the network access node on the secondchannel

In Example 9, the subject matter of any one of Examples 1 to 8 canoptionally include wherein the first channel and the second channel havemutually exclusive frequency ranges on a same wideband carrier.

In Example 10, the subject matter of any one of Examples 1 to 9 canoptionally further include detecting the human object with a sensor.

In Example 11, the subject matter of Example 10 can optionally includewherein the sensor is a passive infrared sensor, a capacitive sensor, aresistive sensor, an optical sensor, a piezoelectric sensor, a camera, amicrophone, a radar detector, or an antenna array-based radar sensor.

In Example 12, the subject matter of Example 10 or 11 can optionallyfurther include determining human object sensing information thatdescribes a distance or a direction of the human object relative to anantenna array of the communication device, wherein determining theestimated RF exposure power includes determining the estimated RFexposure power based on the human object sensing information, the firsttransmit power, and the first antenna beam.

In Example 13, the subject matter of Example 10 or 11 can optionallyfurther include determining, with the sensor, a distance value based ona distance between the human object and an antenna array of thecommunication device, and determining, with the sensor, a directionvalue based on a direction between the human object and an antenna arrayof the communication device, wherein determining the estimated RFexposure power includes determining the estimated RF exposure powerbased on the distance value, the direction value, the first transmitpower, and the first antenna beam.

In Example 14, the subject matter of any one of Examples 1 to 13 canoptionally include wherein the human object is a whole human body or apart of a human body.

In Example 15, the subject matter of any one of Examples 1 to 14 canoptionally include wherein if the estimated RF exposure power is greaterthan the exposure power threshold, the method further includesidentifying a high exposure power limit window scheduled before a lowexposure power limit window in a time-independent exposure power limit,identifying a first timepoint based on a channel switch latency and theend timepoint of the high exposure power limit window, and transmittingsignaling at the first timepoint to trigger a channel switch from thefirst channel to the second channel

In Example 16, the subject matter of Example 15 can optionally includewherein the channel switch takes effect at a second timepointapproximately equal to the first timepoint plus the channel switchlatency.

In Example 17, the subject matter of any one of Examples 1 to 14 canoptionally include wherein if the estimated RF exposure power is greaterthan the exposure power threshold, the method further includesidentifying a high exposure power limit window scheduled before a lowexposure power limit window in a time-independent exposure power limit,and triggering a channel switch from the first channel to the secondchannel based on the timing of the high exposure power limit window.

In Example 18, the subject matter of any one of Examples 1 to 17 canoptionally include wherein transmitting the data on the first channelincludes transmitting the data with a digital transmitter via a radiotransceiver and an antenna array.

Example 19 is a method of performing radio communications at acommunication device, the method including identifying a high exposurepower limit window and a low exposure power limit window in atime-dependent exposure power limit, identifying a first data packetscheduled for transmission and a second data packet scheduled fortransmission, determining a first transmission time for the first datapacket and a second transmission time for the second data packet basedon the time-dependent exposure power limit and further based on a datapacket priority or a data packet size, and transmitting the first datapacket at the first transmission time and transmitting the second datapacket at the second transmission time.

In Example 20, the subject matter of Example 19 can optionally includewherein the high exposure power limit window is a time window that has alarger human radio frequency (RF) exposure power limit than the lowexposure power limit window.

In Example 21, the subject matter of Example 19 or 20 can optionallyinclude wherein the time-dependent exposure power limit is a power limitcurve that restricts human RF exposure power to certain levels atdifferent points in time.

In Example 22, the subject matter of any one of Examples 19 to 21 canoptionally include wherein the low exposure power limit window isscheduled immediately after the high exposure power limit window.

In Example 23, the subject matter of any one of Examples 19 to 22 canoptionally further include determining that the first data packet has ahigher data packet priority than the second data packet.

In Example 24, the subject matter of Example 23 can optionally includewherein determining that the first data packet has a higher data packetpriority than the second data packet is based on Quality of Service(QoS) requirements assigned to the first data packet and the second datapacket.

In Example 25, the subject matter of any one of Examples 19 to 22 canoptionally further include determining that the first data packet has ahigher data packet size than the second data packet.

In Example 26, the subject matter of any one of Examples 23 to 25 canoptionally include wherein determining the first transmission time forthe first data packet and the second transmission time for the seconddata packet includes selecting the first transmission time during thehigh exposure power limit window and selecting the second transmissiontime during the low exposure power limit window.

Example 27 is a communication device including a digital transmitterconfigured to transmit data on a first channel with a first antenna beamand a first transmit power, an estimator configured to determine anestimated radio frequency (RF) exposure power to a human object based onthe first antenna beam and the first transmit power, and a controllerconfigured to determine whether the estimated RF exposure power isgreater than an exposure power threshold, wherein, if the controllerdetermines the estimated RF exposure power is greater than the exposurepower threshold, the controller is configured to switch the digitaltransmitter from the first channel to a second channel with narrowerbandwidth and the digital transmitter is configured to transmit data onthe second channel with a second transmit power lower than the firsttransmit power.

In Example 28, the subject matter of Example 27 can optionally furtherinclude a radio transceiver and an antenna array, wherein the digitaltransmitter is configured to transmit the data on the first channel viathe radio transceiver and the antenna array.

In Example 29, the subject matter of Example 28 can optionally includewherein the antenna array is configured to transmit wireless signals toform the first antenna beam.

In Example 30, the subject matter of any one of Examples 27 to 29 canoptionally include wherein if the estimated RF exposure power is lessthan the exposure power threshold, the digital transmitter is configuredto continue to transmit data on the first channel with the first antennabeam and the first transmit power.

In Example 31, the subject matter of any one of Examples 27 to 30 canoptionally include wherein the controller is configured to switch thedigital transmitter from the first channel to the second channel bycontrolling the digital transmitter to transmit signaling to a networkaccess node for channel switching from the first channel to the secondchannel.

In Example 32, the subject matter of Example 31 can optionally includewherein the digital transmitter is configured to transmit the signalingto the network access node on the second channel

In Example 33, the subject matter of Example 31 or 32 can optionallyfurther include a digital receiver configured to receive, on the secondchannel, a transmission grant for transmitting data on the secondchannel.

In Example 34, the subject matter of any one of Examples 31 to 33 canoptionally include wherein the channel switch is a user equipment(UE)-triggered bandwidth part (BWP) switch procedure, and wherein thesecond channel is a default BWP and the first channel is a non-defaultBWP.

In Example 35, the subject matter of Example 34 can optionally includewherein the controller is further configured to if the estimated RFexposure power is greater than the exposure power threshold, determinewhether the default BWP has narrower bandwidth than the non-default BWP,and trigger the BWP fallback procedure if the default BWP has narrowerbandwidth than the non-default BWP.

In Example 36, the subject matter of Example 31 can optionally includewherein the channel switch is a user equipment (UE)-triggered bandwidthpart (BWP) switch procedure, and wherein the digital transmitter isconfigured to transmit the signaling to the network access node on thesecond channel by transmitting a random access transmission to thenetwork access node on the second channel.

In Example 37, the subject matter of any one of Examples 27 to 36 canoptionally include wherein the first channel and the second channel havemutually exclusive frequency ranges on a same wideband carrier.

In Example 38, the subject matter of any one of Examples 27 to 37 canoptionally further include a sensor configured to detect the humanobject.

In Example 39, the subject matter of Example 38 can optionally includewherein the sensor is a passive infrared sensor, a capacitive sensor, aresistive sensor, an optical sensor, a piezoelectric sensor, a camera, amicrophone, a radar detector, or an antenna array-based radar sensor.

In Example 40, the subject matter of Example 38 or 39 can optionallyinclude wherein the sensor is further configured to determine humanobject sensing information that describes a distance or a direction ofthe human object relative to an antenna array of the communicationdevice, and wherein the estimator is configured to determine theestimated RF exposure power by determining the estimated RF exposurepower based on the human object sensing information, the first transmitpower, and the first antenna beam.

In Example 41, the subject matter of Example 38 or 39 can optionallyinclude wherein the sensor is further configured to determine a distancevalue based on a distance between the human object and an antenna arrayof the communication device, and to determine a direction value based ona direction between the human object and an antenna array of thecommunication device, and wherein the estimator is configured todetermine the estimated RF exposure power by determining the estimatedRF exposure power based on the distance value, the direction value, thefirst transmit power, and the first antenna beam.

In Example 42, the subject matter of any one of Examples 27 to 41 canoptionally include wherein the human object is a whole human body or apart of a human body.

In Example 43, the subject matter of any one of Examples 27 to 42 canoptionally include wherein if the estimated RF exposure power is greaterthan the exposure power threshold the controller is further configuredto identify a high exposure power limit window scheduled before a lowexposure power limit window in a time-independent exposure power limit,and to identify a first timepoint based on a channel switch latency andthe end timepoint of the high exposure power limit window, and thedigital transmitter is further configured to transmit signaling at thefirst timepoint to trigger the channel switch from the first channel tothe second channel

In Example 44, the subject matter of Example 43 can optionally includewherein the channel switch takes effect at a second timepointapproximately equal to the first timepoint plus the channel switchlatency.

In Example 45, the subject matter of any one of Examples 27 to 42 canoptionally include wherein if the estimated RF exposure power is greaterthan the exposure power threshold the controller is further configuredto identify a high exposure power limit window scheduled before a lowexposure power limit window in a time-independent exposure power limit,and to trigger a channel switch from the first channel to the secondchannel based on the timing of the high exposure power limit window.

Example 46 is a communication device including a controller configuredto identify a high exposure power limit window and a low exposure powerlimit window in a time-dependent exposure power limit, identify a firstdata packet scheduled for transmission and a second data packetscheduled for transmission, and determine a first transmission time forthe first data packet and a second transmission time for the second datapacket based on the time-dependent exposure power limit and furtherbased on a data packet priority or a data packet size, and a digitaltransmitter configured to transmit the first data packet at the firsttransmission time and to transmit the second data packet at the secondtransmission time.

In Example 47, the subject matter of Example 46 can optionally furtherinclude a radio transceiver and one or more antennas, wherein thedigital transmitter is configured to transmit the first data packet andthe second data packet via the radio transceiver and the one or moreantennas.

In Example 48, the subject matter of Example 46 or 47 can optionallyinclude wherein the high exposure power limit window is a time windowthat has a larger human radio frequency (RF) exposure power limit thanthe low exposure power limit window.

In Example 49, the subject matter of any one of Examples 46 to 48 canoptionally include wherein the time-dependent exposure power limit is apower limit curve that restricts human RF exposure power to certainlevels at different points in time.

In Example 50, the subject matter of any one of Examples 46 to 49 canoptionally include wherein the low exposure power limit window isscheduled immediately after the high exposure power limit window.

In Example 51, the subject matter of any one of Examples 46 to 50 canoptionally include wherein the controller is further configured todetermine that the first data packet has a higher data packet prioritythan the second data packet.

In Example 52, the subject matter of Example 51 can optionally includewherein the controller is configured to determine that the first datapacket has a higher data packet priority than the second data packetbased on Quality of Service (QoS) requirements assigned to the firstdata packet and the second data packet.

In Example 53, the subject matter of any one of Examples 46 to 50 canoptionally include wherein the controller is further configured todetermine that the first data packet has a higher data packet size thanthe second data packet.

In Example 54, the subject matter of any one of Examples 51 to 53 canoptionally include wherein the controller is configured to determine thefirst transmission time for the first data packet and the secondtransmission time for the second data packet by selecting the firsttransmission time during the high exposure power limit window andselecting the second transmission time during the low exposure powerlimit window.

Example 55 is a non-transitory compute readable medium storinginstructions that, when executed by one or more processors, cause theone or more processors to perform the method of any one of Examples 1 to26.

Example 56 is a communication device including one or more processorsconfigured to perform the method of any one of Examples 1 to 26.

Example 57 is a communication device including means for transmittingdata on a first channel with a first antenna beam and a first transmitpower, means for determining an estimated radio frequency (RF) exposurepower to a human object based on the first antenna beam and the firsttransmit power, means for determining whether the estimated RF exposurepower is greater than an exposure power threshold, and means for, if theestimated RF exposure power is greater than the exposure powerthreshold, switching from the first channel to a second channel withnarrower bandwidth and transmitting data on the second channel with asecond transmit power lower than the first transmit power.

Example 58 is a communication device including means for identifying ahigh exposure power limit window and a low exposure power limit windowin a time-dependent exposure power limit, means for identifying a firstdata packet and a second data packet scheduled for transmission, meansfor determining a first transmission time for the first data packet anda second transmission time for the second data packet based on thetime-dependent exposure power limit and further based on a data packetpriority or a data packet size, and means for transmitting the firstdata packet at the first transmission time and transmitting the seconddata packet at the second transmission time.

Example 59 is a method of performing radio communications at acommunication device, the method including detecting, with a sensor, oneor more objects around the communication device, identifying one or moreblocked sectors of an antenna array that are blocked by the one or moreobjects, selecting, based on the one or more blocked sectors, one ormore candidate sectors of the antenna array to evaluate, and determiningradio link qualities of the one or more candidate sectors.

In Example 60, the subject matter of Example 59 can optionally includewherein determining radio link qualities of the one or more candidatesectors includes performing a beamsweeping procedure with a networkaccess node to determine the radio link qualities of the one or morecandidate sectors.

In Example 61, the subject matter of Example 59 can optionally includewherein determining radio link qualities of the one or more candidatesectors includes performing a sector-level sweep procedure with anetwork access node to determine the radio link qualities of the one ormore candidate sectors.

In Example 62, the subject matter of Example 59 can optionally includewherein determining the radio link quality for a first candidate sectorof the one or more candidate sectors includes controlling the antennaarray to receive a signal with the first candidate sector, and measuringthe signal to obtain the radio link quality the first candidate sector.

In Example 63, the subject matter of Example 62 can optionally includewherein controlling the antenna array to receive the signal with thefirst candidate sector includes applying a set of complex beamformingweights to the antenna elements of the antenna array with digitalbeamforming or radio frequency (RF) phased-array beamforming, whereinthe set of complex beamforming weights forms the first candidate sectoras a radiation pattern of the antenna array.

In Example 64, the subject matter of Example 59 can optionally includewherein determining the radio link quality for a first candidate sectorof the one or more candidate sectors includes controlling the antennaarray to transmit a signal with the first candidate sector, andreceiving a signal from a network access node that indicates the radiolink quality for the first candidate sector.

In Example 65, the subject matter of Example 64 can optionally includewherein controlling the antenna array to transmit a signal with thefirst candidate sector includes applying a set of complex beamformingweights to the antenna elements of the antenna array with digitalbeamforming or radio frequency (RF) phased-array beamforming, whereinthe set of complex beamforming weights forms the first candidate sectoras a radiation pattern of the antenna array.

In Example 66, the subject matter of any one of Examples 59 to 65 canoptionally include wherein determining radio link qualities of the oneor more candidate sectors includes determining radio link qualities foronly the one or more candidate sectors.

In Example 67, the subject matter of any one of Examples 59 to 66 canoptionally include wherein the antenna array is configured to operatewith a plurality of sectors and wherein the one or more blocked sectorsare a reduced subset of the plurality of sectors.

In Example 66, the subject matter of any one of Examples 59 to 66 canoptionally further include selecting a target sector based on the radiolink qualities, and controlling the antenna array to transmit or receivesignals with the target sector.

In Example 69, the subject matter of any one of Examples 59 to 66 canoptionally further include determining, with the sensor, a sensordirection at which the first object is located relative to thecommunication device.

In Example 70, the subject matter of Example 69 can optionally includewherein the sensor direction includes an angle or a range of anglesrelative to the communication device.

In Example 71, the subject matter of any one of Examples 59 to 70 canoptionally further include determining, with the sensor, a distance ofthe first object from the communication device.

In Example 72, the subject matter of any one of Examples 69 to 71 canoptionally include wherein identifying the one or more blocked sectorsof the antenna array includes identifying a first blocked sector of theone or more blocked sectors by determining that the first blocked sectoroverlaps directionally with the sensor direction of the first object.

In Example 73, the subject matter of Example 72 can optionally includewherein the sensor direction of the first object is a first angularrange relative to the communication device and wherein a plurality ofsectors of the antenna array each occupy a respective angular rangerelative to the communication device, and wherein identifying the firstblocked sector includes comparing the first angular range to therespective angular ranges of the plurality of sectors, and determiningthat the first angular range overlaps with the angular range of thefirst blocked sector.

In Example 74, the subject matter of any one of Examples 59 to 73 canoptionally include wherein selecting the one or more candidate sectorsof the antenna array to evaluate includes identifying, from a pluralityof sectors of the antenna array, one or more unblocked sectors that arenot partially or fully blocked by the one or more objects, and includingthe one or more unblocked sectors in the one or more candidate sectors.

In Example 75, the subject matter of any one of Examples 59 to 73 canoptionally include wherein selecting the one or more candidate sectorsof the antenna array to evaluate includes determining, for the one ormore blocked sectors, blocking levels that indicate an amount that eachof the one or more blocked sectors is blocked by the one or moreobjects, and selecting the one or more candidate sectors based on theblocking levels.

In Example 76, the subject matter of Example 75 can optionally includewherein selecting the one or more candidate sectors based on theblocking levels includes identifying a subset of the one or more blockedsectors with blocking levels less than a predefined blocking levelthreshold, and including the subset of the one or more blocked sectorsin the one or more candidate sectors.

In Example 77, the subject matter of any one of Examples 59 to 73 canoptionally include wherein selecting the one or more candidate sectorsof the antenna array to evaluate includes selecting a subset of the oneor more blocked sectors based on a distance of the one or more objectsfrom the communication device, and including the subset of the one ormore blocked sectors in the one or more candidate sectors.

In Example 78, the subject matter of any one of Examples 59 to 73 canoptionally include wherein selecting the one or more candidate sectorsof the antenna array to evaluate includes identifying, from the one ormore blocked sectors, one or more human-blocked sectors that are blockedby a human object, estimating maximum allowable transmit powers for theone or more human-blocked sectors, and selecting the one or morecandidate sectors based on the maximum allowable transmit powers.

In Example 79, the subject matter of Example 78 can optionally includewherein selecting the one or more candidate sectors based on the maximumallowable transmit powers includes identifying a subset of the one ormore human blocked sectors with maximum allowable transmit powersgreater than a predefined threshold, and including the subset of the oneor more human blocked sectors in the one or more candidate sectors.

In Example 80, the subject matter of Example 78 or 79 can optionallyinclude wherein estimating the maximum allowable transmit powers for afirst human-blocked sector of the one or more human-blocked sectorsincludes determining a distance from the communication device that ahuman object is in the first human-blocked sector, and estimating themaximum allowable transmit power for the first human-blocked sectorbased on the distance.

In Example 81, the subject matter of any one of Examples 78 to 80 canoptionally further include selecting a target sector based on the radiolink qualities and the maximum allowable transmit powers, andcontrolling the antenna array to transmit or receive signals with thetarget sector.

In Example 82, the subject matter of any one of Examples 59 to 81 canoptionally include wherein the sensor is an infrared sensor, acapacitive sensor, a resistive sensor, an optical sensor, apiezoelectric sensor, a camera, a microphone, or a radar sensor.

In Example 83, the subject matter of any one of Examples 59 to 80 canoptionally include wherein the sensor includes the antenna array and aradar controller, and wherein detecting the one or more objects aroundthe communication device includes controlling the antenna array totransmit a transmit signal, controlling the antenna array to receive, asa reflected signal, the transmit signal after the transmit signalreflects back off the one or more objects, and processing the reflectedsignal to detect the one or more objects.

In Example 84, the subject matter of Example 83 can optionally includewherein processing the reflected signal to detect the one or moreobjects includes detecting the one or more objects based on a phasedifference between the transmit signal and the reflected signal.

In Example 85, the subject matter of Example 83 or 84 can optionallyfurther include classifying the one or more objects as human ornon-human based on the reflected signal by processing the reflectedsignal to detect Doppler or micro-Doppler effects in the reflectedsignal, and classifying the first object as a human object based on theDoppler or micro-Doppler effects.

In Example 86, the subject matter of Example 83 or 84 can optionallyfurther include classifying the one or more objects as human ornon-human based on the reflected signal by determining, based on thereflected signal, a distance of the first object from the communicationdevice, and correlating the distance with a reflectivity of the firstobject to determine a correlation, and classifying the first object as ahuman object based on the correlation.

In Example 87, the subject matter of Example 83 or 84 can optionallyfurther include classifying the one or more objects as human ornon-human based on the reflected signal by measuring, based on thereflected signal, a reflectivity of the first object across a frequencyrange to determine a frequency signature, and comparing the frequencysignature with a pre-characterized human tissue frequency signature, andclassifying the first object as a human object based on the comparing.

Example 88 is a method of performing radio communications at acommunication device, the method including detecting, with a sensor, oneor more human objects around the communication device, identifying oneor more human-blocked sectors of an antenna array that are blocked bythe one or more human objects, estimating a maximum allowable transmitpower for the one or more human-blocked sectors, selecting one or morecandidate sectors of the antenna array to evaluate based on maximumallowable transmit powers, and determining radio link qualities of theone or more candidate sectors.

In Example 89, the subject matter of Example 88 can optionally includewherein detecting with the sensor the one or more human objects includesdetecting, with the sensor, a plurality of objects around thecommunication device, and determining that a first object of theplurality objects is a human object and including the first object inthe one or more human objects.

In Example 90, the subject matter of Example 88 can optionally includewherein the sensor is a radar, and wherein determining that the firstobject is a human object includes controlling the radar to transmit atransmit signal that radiates outward from the communication device,controlling the radar to receive, as a reflected signal, the transmitsignal after the transmit signal reflects back off first object, andclassifying the first object as a human object based on the reflectedsignal.

In Example 91, the subject matter of Example 90 can optionally includewherein classifying the first object as a human object based on thereflected signal includes processing the reflected signal to detectDoppler or micro-Doppler effects in the reflected signal, andclassifying the first object as a human object based on the Doppler ormicro-Doppler effects.

In Example 92, the subject matter of Example 90 can optionally includewherein classifying the first object as a human object based on thereflected signal includes determining, based on the reflected signal, adistance of the first object from the communication device, andcorrelating the distance with a reflectivity of the first object todetermine a correlation, and classifying the first object as a humanobject based on the correlation.

In Example 93, the subject matter of Example 90 can optionally includewherein classifying the first object as a human object based on thereflected signal includes measuring, based on the reflected signal, areflectivity of the first object across a frequency range to determine afrequency signature, and comparing the frequency signature with apre-characterized human tissue frequency signature, and classifying thefirst object as a human object based on the comparing.

In Example 94, the subject matter of any one of Examples 90 to 93 canoptionally include wherein the radar includes the antenna array and aradar controller.

In Example 95, the subject matter of Example 94 can optionally includewherein controlling the radar to transmit the transmit signal includescontrolling, with the radar controller, the antenna array to transmitthe transmit signal, and wherein controlling the radar to receive thereflected signal includes controlling, with the radar controller, theantenna array to receive the reflected signal.

In Example 96, the subject matter of any one of Examples 88 to 95 canoptionally include wherein selecting one or more candidate sectors ofthe antenna array to evaluate based on the maximum allowable transmitpowers includes identifying a subset of the one or more human-blockedsectors with maximum allowable transmit powers greater than a predefinedthreshold, and including the subset of the one or more human-blockedsectors in the one or more candidate sectors.

In Example 97, the subject matter of any one of Examples 88 to 96 canoptionally further include detecting, with the sensor, one or morenon-human objects around the communication device, identifying one ormore non-human blocked sectors of the antenna array that are blocked bythe one or more non-human objects, and including a subset of the one ormore non-human blocked sectors in the one or more candidate sectors forwhich radio link qualities are evaluated.

In Example 98, the subject matter of Example 97 can optionally furtherinclude selecting a target sector based on the radio link qualities andthe maximum allowable transmit powers, and controlling the antenna arrayto transmit or receive signals with the target sector.

In Example 99, the subject matter of Example 98 can optionally includewherein selecting the target sector based on the radio link qualitiesand the maximum allowable transmit powers includes scaling down theradio link qualities of the one or more human-blocked sectors based ontheir respective maximum allowable transmit powers to obtain weightedradio link qualities for the one or more human-blocked sectors, andselecting, as the target sector, the sector of the one or more candidatesectors that has the radio link quality or the weighted radio linkquality with the highest value.

In Example 100, the subject matter of any one of Examples 88 to 96 canoptionally further include selecting a target sector based on the radiolink qualities and the maximum allowable transmit powers, andcontrolling the antenna array to transmit or receive signals with thetarget sector.

In Example 101, the subject matter of any one of Examples 88 to 100 canoptionally include wherein determining radio link qualities of the oneor more candidate sectors includes performing a beamsweeping procedurewith a network access node to determine the radio link qualities of theone or more candidate sectors.

In Example 102, the subject matter of any one of Examples 88 to 100 canoptionally include wherein determining radio link qualities of the oneor more candidate sectors includes performing a sector-level sweepprocedure with a network access node to determine the radio linkqualities of the one or more candidate sectors.

In Example 103, the subject matter of any one of Examples 88 to 100 canoptionally include wherein determining the radio link quality for afirst candidate sector of the one or more candidate sectors includescontrolling the antenna array to receive a signal with the firstcandidate sector, and measuring the signal to obtain the radio linkquality the first candidate sector.

In Example 104, the subject matter of Example 103 can optionally includewherein controlling the antenna array to receive the signal with thefirst candidate sector includes controlling the antenna array to apply aset of complex beamforming weights to the antenna elements of theantenna array, wherein the set of complex beamforming weights forms thefirst candidate sector as a radiation pattern of the antenna array.

In Example 105, the subject matter of any one of Examples 88 to 100 canoptionally include wherein determining the radio link quality for afirst candidate sector of the one or more candidate sectors includescontrolling the antenna array to transmit a signal with the firstcandidate sector, and receiving a signal from a network access node thatindicates the radio link quality for the first candidate sector.

In Example 106, the subject matter of Example 105 can optionally includewherein determining the radio link quality for a first candidate sectorincludes controlling the antenna array to apply a set of complexbeamforming weights to the antenna elements of the antenna array,wherein the set of complex beamforming weights forms the first candidatesector as a radiation pattern of the antenna array.

In Example 107, the subject matter of any one of Examples 88 to 107 canoptionally include wherein determining radio link qualities of the oneor more candidate sectors includes determining radio link qualities foronly the one or more candidate sectors.

Example 108 is a communication device including a sensor configured todetect one or more objects around the communication device, and acontroller configured to identify one or more blocked sectors of anantenna array that are blocked by the one or more objects, select, basedon the one or blocked sectors, one or more candidate sectors of theantenna array to evaluate, and determine radio link qualities of the oneor more candidate sectors.

In Example 109, the subject matter of Example 108 can optionally furtherinclude the antenna array and a radio transceiver.

In Example 110, the subject matter of Example 108 can optionally furtherinclude a digital transmitter and a digital receiver that are connectedto the controller, wherein the digital transmitter is configured totransmit signals via the antenna array and the radio transceiver andwherein the digital receiver is configured to receive signals via theantenna array and the radio transceiver.

In Example 111, the subject matter of any one of Examples 108 to 110 canoptionally include wherein the controller is configured to determine theradio link qualities of the one or more candidate sectors by performinga beamsweeping procedure with a network access node to determine theradio link qualities of the one or more candidate sectors.

In Example 112, the subject matter of any one of Examples 108 to 110 canoptionally include wherein the controller is configured to determine theradio link qualities of the one or more candidate sectors by performinga sector-level sweep procedure with a network access node to determinethe radio link qualities of the one or more candidate sectors.

In Example 113, the subject matter of any one of Examples 108 to 110 canoptionally include wherein the controller is configured to determine theradio link quality for a first candidate sector of the one or morecandidate sectors by controlling the antenna array to receive a signalwith the first candidate sector, and controlling a digital receiver tomeasure the signal to obtain the radio link quality the first candidatesector.

In Example 114, the subject matter of Example 113 can optionally includewherein the controller is configured to control the antenna array toreceive the signal with the first candidate sector by applying a set ofcomplex beamforming weights to the antenna elements of the antenna arraywith digital beamforming or radio frequency (RF) phased-arraybeamforming, wherein the set of complex beamforming weights forms thefirst candidate sector as a radiation pattern of the antenna array.

In Example 115, the subject matter of any one of Examples 108 to 110 canoptionally include wherein the controller is configured to determine theradio link quality for a first candidate sector of the one or morecandidate sectors by controlling the antenna array to transmit a signalwith the first candidate sector, and controlling a digital receiver toreceive a signal from a network access node that indicates the radiolink quality for the first candidate sector.

In Example 116, the subject matter of Example 115 can optionally includewherein the controller is configured to control the antenna array totransmit the signal with the first candidate sector by applying a set ofcomplex beamforming weights to the antenna elements of the antenna arraywith digital beamforming or radio frequency (RF) phased-arraybeamforming, wherein the set of complex beamforming weights forms thefirst candidate sector as a radiation pattern of the antenna array.

In Example 117, the subject matter of any one of Examples 108 to 116 canoptionally include wherein the controller is configured to determineradio link qualities for only the one or more candidate sectors.

In Example 118, the subject matter of any one of Examples 108 to 117 canoptionally include wherein the antenna array is configured to operatewith a plurality of sectors and wherein the one or more blocked sectorsare a reduced subset of the plurality of sectors.

In Example 119, the subject matter of any one of Examples 108 to 118 canoptionally include wherein the controller is further configured toselect a target sector based on the radio link qualities, and controlthe antenna array to transmit or receive signals with the target sector.

In Example 120, the subject matter of any one of Examples 108 to 119 canoptionally include wherein the sensor is configured to determine asensor direction at which the first object is located relative to thecommunication device.

In Example 121, the subject matter of Example 120 can optionally includewherein the sensor direction includes an angle or a range of anglesrelative to the communication device.

In Example 122, the subject matter of any one of Examples 108 to 121 canoptionally include wherein the sensor is further configured to determinea distance of the first object from the communication device.

In Example 123, the subject matter of any one of Examples 120 to 122 canoptionally include wherein the controller is configured to identify theone or more blocked sectors of the antenna array by identifying a firstblocked sector of the one or more sectors by determining that the firstblocked sector overlaps directionally with the sensor direction of thefirst object.

In Example 124, the subject matter of Example 123 can optionally includewherein the sensor direction of the first object is a first angularrange relative to the communication device and wherein a plurality ofsectors of the antenna array each occupy a respective angular rangerelative to the communication device, and wherein the controller isconfigured to identify the first blocked sector by comparing the firstangular range to the respective angular ranges of the plurality ofsectors, and determining that the first angular range overlaps with theangular range of the first blocked sector.

In Example 125, the subject matter of any one of Examples 108 to 124 canoptionally include wherein the controller is configured to select theone or more candidate sectors of the antenna array to evaluate byidentifying, from a plurality of sectors of the antenna array, one ormore unblocked sectors that are not partially or fully blocked by theone or more objects, and including the one or more unblocked sectors inthe one or more candidate sectors.

In Example 125, the subject matter of any one of Examples 108 to 124 canoptionally include wherein the controller is configured to select theone or more candidate sectors of the antenna array to evaluate bydetermining, for the one or more blocked sectors, blocking levels thatindicate an amount that each of the one or more blocked sectors isblocked by the one or more objects, and selecting the one or morecandidate sectors based on the blocking levels.

In Example 127, the subject matter of Example 125 can optionally includewherein the controller is configured to select the one or more candidatesectors based on the blocking levels by identifying a subset of the oneor more blocked sectors with blocking levels less than a predefinedblocking level threshold, and including the subset of the one or moreblocked sectors in the one or more candidate sectors.

In Example 128, the subject matter of any one of Examples 108 to 124 canoptionally include wherein controller is configured to select the one ormore candidate sectors of the antenna array to evaluate by selecting asubset of the one or more blocked sectors based on a distance of the oneor more objects from the communication device, and including the subsetof the one or more blocked sectors in the one or more candidate sectors.

In Example 129, the subject matter of any one of Examples 108 to 124 canoptionally include wherein the controller is configured to select theone or more candidate sectors of the antenna array to evaluate byidentifying, from the one or more blocked sectors, one or morehuman-blocked sectors that are blocked by a human object, estimatingmaximum allowable transmit powers for the one or more human-blockedsectors, and selecting the one or more candidate sectors based on themaximum allowable transmit powers.

In Example 130, the subject matter of Example 129 can optionally includewherein the controller is configured to select the one or more candidatesectors based on the maximum allowable transmit power by identifying asubset of the one or more human blocked sectors with maximum allowabletransmit powers less than a predefined threshold, and including thesubset of the one or more human blocked sectors in the one or morecandidate sectors.

In Example 131, the subject matter of Example 129 or 130 can optionallyinclude wherein the controller is configured to estimate the maximumallowable transmit powers for a first human-blocked sector of the one ormore human-blocked sectors by determining a distance from thecommunication device that a human object is in the first human-blockedsector, and estimating the maximum allowable transmit power for thefirst human-blocked sector based on the distance.

In Example 132, the subject matter of any one of Examples 129 to 131 canoptionally include wherein the controller is further configured toselect a target sector based on the radio link qualities and the maximumallowable transmit powers, and control the antenna array to transmit orreceive signals with the target sector.

In Example 133, the subject matter of any one of Examples 108 to 132 canoptionally include wherein the sensor is an infrared sensor, acapacitive sensor, a resistive sensor, an optical sensor, apiezoelectric sensor, a camera, a microphone, or a radar sensor.

In Example 134, the subject matter of any one of Examples 108 to 132 canoptionally include wherein the sensor includes the antenna array and aradar controller, and wherein the radar controller is configured todetect the one or more objects around the communication device bycontrolling the antenna array to transmit a transmit signal, controllingthe antenna array to receive, as a reflected signal, the transmit signalafter the transmit signal reflects back off the one or more objects, andprocessing the reflected signal to detect the one or more objects.

In Example 135, the subject matter of any one of Examples 108 to 132 canoptionally include wherein the radar controller is configured to processthe reflected signal to detect the one or more objects by detecting theone or more objects based on a phase difference between the transmitsignal and the reflected signal.

In Example 136, the subject matter of Example 134 or 135 can optionallyinclude wherein the radar controller is configured to classify the oneor more objects as human or non-human based on the reflected signal byprocessing the reflected signal to detect Doppler or micro-Dopplereffects in the reflected signal, and classifying the first object as ahuman object based on the Doppler or micro-Doppler effects.

In Example 137, the subject matter of Example 134 or 135 can optionallyinclude wherein the radar controller is configured to classify the oneor more objects as human or non-human based on the reflected signal bydetermining, based on the reflected signal, a distance of the firstobject from the communication device, and correlating the distance witha reflectivity of the first object to determine a correlation, andclassifying the first object as a human object based on the correlation.

In Example 138, the subject matter of Example 134 or 135 can optionallyinclude wherein the radar controller is configured to classify the oneor more objects as human or non-human based on the reflected signal bymeasuring, based on the reflected signal, a reflectivity of the firstobject across a frequency range to determine a frequency signature,comparing the frequency signature with a pre-characterized human tissuefrequency signature, and classifying the first object as a human objectbased on the comparing.

Example 139 is a communication device including a sensor configured todetect one or more human objects around the communication device, and acontroller configured to identify one or more human-blocked sectors ofan antenna array that are blocked by one or more human objects, estimatea maximum allowable transmit power for the one or more human-blockedsectors, select one or more candidate sectors of the antenna array toevaluate based on maximum allowable transmit powers, and determine radiolink qualities of the one or more candidate sectors.

In Example 140, the subject matter of Example 139 can optionally furtherinclude the antenna array and a radio transceiver.

In Example 141, the subject matter of Example 139 can optionally furtherinclude a digital transmitter and a digital receiver that are connectedto the controller, wherein the digital transmitter is configured totransmit signals via the antenna array and the radio transceiver andwherein the digital receiver is configured to receive signals via theantenna array and the radio transceiver.

In Example 142, the subject matter of any one of Examples 139 to 141 canoptionally include wherein the sensor is configured to detect the one ormore human objects by detecting a plurality of objects around thecommunication device, and determining that a first object of theplurality objects is a human object and including the first object inthe one or more human objects.

In Example 143, the subject matter of Example 142 can optionally includewherein the sensor is a radar, and wherein the sensor is configured todetermine that the first object is a human object by controlling theradar to transmit a transmit signal that radiates outward from thecommunication device, controlling the radar to receive, as a reflectedsignal, the transmit signal after the transmit signal reflects back offfirst object, and classifying the first object as a human object basedon the reflected signal.

In Example 144, the subject matter of Example 143 can optionally includewherein the sensor is configured to classify the first object as a humanobject based on the reflected signal by processing the reflected signalto detect Doppler or micro-Doppler effects in the reflected signal, andclassifying the first object as a human object based on the Doppler ormicro-Doppler effects.

In Example 145, the subject matter of Example 143 can optionally includewherein the sensor is configured to classify the first object as a humanobject based on the reflected signal by determining, based on thereflected signal, a distance of the first object from the communicationdevice, correlating the distance with a reflectivity of the first objectto determine a correlation, and classifying the first object as a humanobject based on the correlation.

In Example 146, the subject matter of Example 143 can optionally includewherein the sensor is configured to classify the first object as a humanobject based on the reflected signal by measuring, based on thereflected signal, a reflectivity of the first object across a frequencyrange to determine a frequency signature, comparing the frequencysignature with a pre-characterized human tissue frequency signature, andclassifying the first object as a human object based on the comparing.

In Example 147, the subject matter of any one of Examples 143 to 146 canoptionally include wherein the radar includes the antenna array and aradar controller.

In Example 148, the subject matter of Example 147 can optionally includewherein the sensor is configured to control the radar to transmit thetransmit signal by controlling, with the radar controller, the antennaarray to transmit the transmit signal, and wherein the sensor isconfigured to control the radar to receive the reflected signal includesby controlling, with the radar controller, the antenna array to receivethe reflected signal.

In Example 149, the subject matter of any one of Examples 139 to 148 canoptionally include wherein the controller is configured to select theone or more candidate sectors of the antenna array to evaluate based onthe maximum allowable transmit powers by identifying a subset of the oneor more human-blocked sectors with maximum allowable transmit powersgreater than a predefined threshold, and including the subset of the oneor more human-blocked sectors in the one or more candidate sectors.

In Example 150, the subject matter of any one of Examples 139 to 149 canoptionally include wherein the sensor is further configured to detectone or more non-human objects around the communication device, andwherein the controller is further configured to identify one or morenon-human blocked sectors of the antenna array that are blocked by theone or more non-human objects, and to include a subset of the one ormore non-human blocked sectors in the one or more candidate sectors forwhich radio link qualities are evaluated.

In Example 151, the subject matter of Example 150 can optionally includewherein the controller is further configured to select a target sectorbased on the radio link qualities and the maximum allowable transmitpowers, and to control the antenna array to transmit or receive signalswith the target sector.

In Example 152, the subject matter of Example 151 can optionally includewherein the controller is configured to select the target sector basedon the radio link qualities and the maximum allowable transmit powers byscaling down the radio link qualities of the one or more human-blockedsectors based on their respective maximum allowable transmit powers toobtain weighted radio link qualities for the one or more human-blockedsectors, and selecting, as the target sector, the sector of the one ormore candidate sectors that has the radio link quality or the weightedradio link quality with the highest value.

In Example 153, the subject matter of any one of Examples 139 to 152 canoptionally include wherein the controller is further configured toselect a target sector based on the radio link qualities and the maximumallowable transmit powers, and to control the antenna array to transmitor receive signals with the target sector.

In Example 154, the subject matter of any one of Examples 139 to 153 canoptionally include wherein the controller is configured to determine theradio link qualities for the one or more candidate sectors by performinga beamsweeping procedure with a network access node to determine theradio link qualities of the one or more candidate sectors.

In Example 155, the subject matter of any one of Examples 139 to 154 canoptionally include wherein the controller is configured to determine theradio link qualities for the one or more candidate sectors by performinga sector-level sweep procedure with a network access node to determinethe radio link qualities of the one or more candidate sectors.

In Example 156, the subject matter of any one of Examples 139 to 155 canoptionally include wherein the controller is configured to determine theradio link quality for a first candidate sector of the one or morecandidate sectors by controlling the antenna array to receive a signalwith the first candidate sector, and measuring the signal to obtain theradio link quality the first candidate sector.

In Example 157, the subject matter of Example 156 can optionally includewherein the controller is configured to control the antenna array toreceive the signal with the first candidate sector by controlling theantenna array to apply a set of complex beamforming weights to theantenna elements of the antenna array, wherein the set of complexbeamforming weights forms the first candidate sector as a radiationpattern of the antenna array.

In Example 158, the subject matter of any one of Examples 139 to 155 canoptionally include wherein the controller is configured to determine theradio link quality for a first candidate sector of the one or morecandidate sectors by controlling the antenna array to transmit a signalwith the first candidate sector, and receiving a signal from a networkaccess node that indicates the radio link quality for the firstcandidate sector.

In Example 159, the subject matter of Example 158 can optionally includewherein the controller is configured to control the antenna array totransmit the signal with the first candidate sector by controlling theantenna array to apply a set of complex beamforming weights to theantenna elements of the antenna array, wherein the set of complexbeamforming weights forms the first candidate sector as a radiationpattern of the antenna array.

In Example 160, the subject matter of any one of Examples 139 to 155 canoptionally include wherein the controller is configured to determine theradio link qualities for only the one or more candidate sectors.

Example 161 is a non-transitory computer readable medium storinginstructions that, when executed by one or more processors of acommunication device, cause the communication device to perform themethod of any one of Examples 59 to 107.

Example 162 is a communication device including one or more processorsconfigured to perform the method of any one of Examples 59 to 107.

In Example 163, the subject matter of Example(s) 163 may include acommunication device including an evaluator configured to evaluate oneor more criteria, wherein a first criterion of the one or more criteriaincludes detecting an object; a determiner configured to determine oneor more beam pairs from a plurality of potential beam pairs to use incommunications with a second device based on the evaluation of the oneor more criteria and transmit an indication of one or more partner-sidebeams of a selected beam pair of the one or more beam pairs to thesecond device; and a beam controller configured to adjust an antenna tocommunicate with the second device via a device-side beam of theselected beam pair.

In Example 164, the subject matter of Example(s) 163 may include whereinthe object is an animate object.

In Example 165, the subject matter of Example(s) 164 may include whereinthe animate object is a human body.

In Example 166, the subject matter of Example(s) 165 may include one ormore detectors configured to detect the object.

In Example 167, the subject matter of Example(s) 166 may include whereinthe one or more detectors include one or more of a passive infraredsensor, a capacitive sensor, a resistive sensor, an optical sensor, apiezoelectric sensor, a camera, a microphone, a proximity sensor, aproximity detector, or a radar detector.

In Example 168, the subject matter of Example(s) 163-167 may includewherein the one or more criteria includes a maximum power exposure (MPE)threshold to electromagnetic radiation.

In Example 169, the subject matter of Example(s) 168 may include whereinthe MPE threshold is defined by a regulatory authority.

In Example 170, the subject matter of Example(s) 168-169 may includewherein the determiner is configured to determine the one or more beampairs based on the detection of the object and the MPE threshold.

In Example 171, the subject matter of Example(s) 170 may include whereinthe determiner is configured to determine the one or more beam pairs bydetermining which of the plurality of potential beam pairs do not exceedthe MPE threshold in a direction of the detected object.

In Example 172, the subject matter of Example(s) 163-171 may includewherein the one or more criteria includes a channel quality between thecommunication device and the second device for the plurality ofpotential beam pairs.

In Example 173, the subject matter of Example(s) 172 may include whereinthe one or more criteria includes a channel quality between thecommunication device and the second device for the one or more beampairs.

In Example 174, the subject matter of Example(s) 172-173 may includewherein the determiner is configured to select the selected beam pairfrom the one or more beam pairs based on having the highest channelquality.

In Example 175, the subject matter of Example(s) 172-174 may includewherein the determiner is configured to measure each respective channelquality of the plurality of potential beam pairs from one or morereference signals on each of the plurality of potential beam pairs.

In Example 176, the subject matter of Example(s) 172-175 may includewherein the determiner is configured to measure each respective channelquality of the one or more beam pairs from one or more reference signalson each of the one or more beam pairs.

In Example 177, the subject matter of Example(s) 175-176 may includewherein the measuring of each of the respective channel quality of theone or more reference signals includes measuring L1-RSRP.

In Example 178, the subject matter of Example(s) 175-177 may includewherein the measuring of each of the respective channel quality of theone or more reference signals includes measuring asignal-to-interference-plus-noise ratio (SINR).

In Example 179, the subject matter of Example(s) 175-178 may includewherein the measuring of each of the respective channel quality of theone or more reference signals includes measuring a mutual information(MI) between a transmitted signal and a corresponding received signal.

In Example 180, the subject matter of Example(s) 163-179 may includewherein the determiner is configured to transmit the indication to thesecond device via a beam recovery request to the second device.

In Example 181, the subject matter of Example(s) 180 may include whereinthe beam recovery requests includes the one or more partner-side beams.

In Example 182, the subject matter of Example(s) 181 may include whereinthe beam recovery request includes a priority order of the one or morepartner-side beams, wherein at least one of the one or more partner-sidebeams has highest priority.

In Example 183, the subject matter of Example(s) 163-182 may includewherein the communication device is configured to switch to thedevice-side beam according to a scheduling parameter with the seconddevice.

In Example 184, the subject matter of Example(s) 163-183 may include areceiver configured to receive a downlink control information (DCI) fromthe second device after the adjustment to the device-side beam.

In Example 185, the subject matter of Example(s) 163-184 may include theevaluator configured to update the evaluation of the one or morecriteria.

In Example 186, the subject matter of Example(s) 185 may include thedeterminer configured to determine one or more updated beam pairs fromthe plurality of potential beam pairs based on the updated evaluation ofthe one or more criteria.

In Example 187, the subject matter of Example(s) 186 may include whereinthe beam controller is configured to adjust the device-side beam to anupdated device-side beam selected from the one or more updated beampairs and transmit an updated one or more partner-side beams to thesecond device.

In Example 188, the subject matter of Example(s) 163-187 may include theantenna including one or more antenna arrays each including a pluralityof antenna elements.

In Example 189, the subject matter of Example(s) 188 may include whereinthe beam controller adjusts the antenna by controlling beamformingweights, including a gain factor or a phase factor, applied to each theplurality of antenna elements.

In Example 190, a communication device including a beam controllerconfigured to control an antenna to communicate with a second device viaa device-side beam of a beam pair, wherein the second devicecommunicates with the communication device via a partner-side beam ofthe beam pair; an evaluator configured to evaluate one or more criteria;and a determiner configured to update the beam pair based on theevaluation of the one or more criteria, wherein the beam controlleradjusts the device-side beam to an updated device-side beam of theupdated beam pair, and the updated partner-side beam of the beam pair iscommunicated to the second device.

In Example 191, the subject matter of Example(s) 190 may include whereinthe evaluation of the one or more criteria includes one or more of adetection of an object, a maximum power exposure (MPE) toelectromagnetic radiation, or a channel quality between thecommunication device and the second device for the one or more beampairs.

In Example 192, a communication device including one or more processorsconfigured to evaluate one or more criteria; determine one or more beampairs from a plurality of potential beam pairs to use in communicationswith a second device based on the one or more criteria; transmit anindication of a one or more partner-side beams of a selected beam pairof the one or more beam pairs to the second device; and adjust anantenna of the communication device to communicate with the seconddevice via a device-side beam of the selected beam pair.

In Example 193, a communication device including means to evaluate oneor more criteria; means to determine one or more beam pairs from aplurality of potential beam pairs to use in communications with a seconddevice based on the one or more criteria; means to transmit anindication of a one or more partner-side beams of a selected beam pairof the one or more beam pairs to the second device; and means to adjustan antenna of the communication device to communicate with the seconddevice via a device-side beam of the selected beam pair.

In Example 194, a method for a communication device to conduct wirelesscommunications, the method including evaluating one or more criteria,wherein the one or more criteria includes detecting an object;determining one or more beam pairs from a plurality of potential beampairs to use in communications with a second device based on the one ormore criteria; transmitting an indication of a one or more partner-sidebeams of a selected beam pair of the one or more beam pairs to thesecond device; and adjusting an antenna of the communication device tocommunicate with the second device via a device-side beam of theselected beam pair.

In Example 195, the subject matter of Example(s) 194 may include whereinthe object is an animate object.

In Example 196, the subject matter of Example(s) 195 may include whereinthe animate object is a human body.

In Example 197, the subject matter of Example(s) 194-196 may includedetecting the object with one or more detectors of the communicationdevice.

In Example 198, the subject matter of Example(s) 197 may include whereinthe one or more detectors include one or more of a passive infraredsensor, a capacitive sensor, a resistive sensor, an optical sensor, apiezoelectric sensor, a camera, a proximity sensor, a proximitydetector, or a radar detector.

In Example 199, the subject matter of Example(s) 194-198 may includewherein evaluating the one or more criteria includes evaluating amaximum power exposure (MPE) threshold to electromagnetic radiation.

In Example 200, the subject matter of Example(s) 199 may include whereinthe MPE is defined by a regulatory authority.

In Example 201, the subject matter of Example(s) 199-200 may includewherein the determining of the one or more beam pairs is based on thedetection of the object and the MPE threshold.

In Example 202, the subject matter of Example(s) 201 may includedetermining the one or more beam pairs by determining which of theplurality of potential beam pairs do not exceed the MPE threshold in adirection of the detected object.

In Example 203, the subject matter of Example(s) 194-202 may includewherein evaluating of the one or more criteria includes measuring achannel quality between the communication device and the second devicefor the plurality of potential beam pairs.

In Example 204, the subject matter of Example(s) 203 may include whereinevaluating of the one or more criteria includes measuring a channelquality between the communication device and the second device for theone or more beam pairs.

In Example 205, the subject matter of Example(s) 203-204 may includeselecting the selected beam pair from the one or more beam pairs basedon having the highest channel quality.

In Example 206, the subject matter of Example(s) 203-205 may includemeasuring each respective channel quality of the plurality of potentialbeam pairs from one or more reference signals on each of the pluralityof potential beam pairs.

In Example 207, the subject matter of Example(s) 203-206 may includemeasuring each respective channel quality of the one or more beam pairsfrom one or more reference signals on each of the one or more beampairs.

In Example 208, the subject matter of Example(s) 206-207 may includewherein the measuring of each of the respective channel quality of theone or more reference signals includes measuring L1-RSRP.

In Example 209, the subject matter of Example(s) 206-208 may includewherein the measuring of each of the respective channel quality of theone or more reference signals includes measuring asignal-to-interference-plus-noise ratio (SINR).

In Example 210, the subject matter of Example(s) 206-209 may includewherein the measuring of each of the respective channel quality of theone or more reference signals includes measuring a mutual information(MI) between a transmitted signal and a corresponding received signal.

In Example 211, the subject matter of Example(s) 194-210 may includetransmitting the indication to the second device via a beam recoveryrequest to the second device.

In Example 212, the subject matter of Example(s) 211 may include whereinthe beam recovery requests includes the one or more partner-side beams.

In Example 213, the subject matter of Example(s) 212 may include whereinthe beam recovery request includes a priority order of the one or morepartner-side beams, wherein at least one of the one or more partner-sidebeams has highest priority.

In Example 214, the subject matter of Example(s) 194-213 may includeswitching to the device-side beam according to a scheduling parameterwith the second device.

In Example 215, the subject matter of Example(s) 194-214 may includereceiving a downlink control information (DCI) from the second deviceafter the adjustment to the device-side beam.

In Example 216, the subject matter of Example(s) 194-216 may includeupdating the evaluation of the one or more criteria.

In Example 217, the subject matter of Example(s) 216 may includedetermining an updated one or more beam pairs from the plurality ofpotential beam pairs based on the updated evaluation of the one or morecriteria.

In Example 218, a method for a communication device to perform wirelesscommunications, the method including communicating with a second devicevia a device-side beam of a beam pair, wherein the second devicecommunicates with the communication device via a partner-side beam ofthe beam pair; evaluating one or more criteria; and updating a beam pairbased on the evaluation of the one or more criteria, wherein theupdating of the beam pair includes adjusting the device-side beam to anupdated device-side beam of the updated beam pair, and communicating anupdated partner-side beam of the updated beam pair to the second device.

In Example 219, the subject matter of Example(s) 218 may include whereinthe evaluation of the one or more criteria includes one or more of adetection of an object, a maximum power exposure (MPE) toelectromagnetic radiation, or a channel quality between thecommunication device and the second device for the one or more beampairs.

In Example 220, one or more non-transitory computer-readable mediastoring instructions thereon that, when executed by at least oneprocessor of a communication device, direct the communication device toperform the method of any one of Examples 194-219.

In Example 221, a communication device including one or more detectorsconfigured to detect one or more objects; a beam controller configuredto control one or more antenna arrays to generate a plurality of beamsaccording to a beam scheme based on the one or more detected objects,wherein the beam scheme implements the plurality of beams according toat least one of: over an angular range with respect to the communicationdevice, wherein a first beam of the plurality of beams has a differentangle with respect to the communication device than a second beam of theplurality of beams, and each beam of the plurality of beams ismaintained based on a predetermined time pattern, or a selectivewidening or narrowing of at least one beam of the plurality of beamswith respect to another beam of the plurality of beams.

In Example 222, the subject matter of Example(s) 221 may include whereinthe beam controller is configured to implement the plurality of beamsover an angular range with respect to the communication device and theselective widening or narrowing.

In Example 223, the subject matter of Example(s) 221-222 may includewherein each of the plurality of beams' respective angles are selectedfrom a plurality of angles in a predefined set.

In Example 224, the subject matter of Example(s) 223 may include whereineach angle in the predefined set has a discrete angular change withrespect to at least one other angle in the predefined set.

In Example 225, the subject matter of Example(s) 221-224 may includewherein the beam controller is configured to schedule the plurality ofbeams to cover the angular range according to a round robin mechanism.

In Example 226, the subject matter of Example(s) 225 may include whereinthe beam controller determines a repetition period of each cycle of theround robin mechanism based on a maximum power exposure (MPE) threshold.

In Example 227, the subject matter of Example(s) 226 may include whereinthe MPE threshold is determined based on one or more regulations orrules by a regulatory authority.

In Example 228, the subject matter of Example(s) 221-227 may includewherein the selective widening or narrowing of the at least one beam ofthe plurality of beams with respect to the other beam of the pluralityof beams is based on a maximum power exposure (MPE) threshold.

In Example 229, the subject matter of Example(s) 228 may include whereina total transmission power of the selective widening or narrowing of theat least one beam of the plurality of beams with respect to the otherbeam of the plurality of beams remains the same.

In Example 230, the subject matter of Example(s) 228-229 may includewherein the widening or narrowing is performed in at least one of ahorizontal, a vertical, or a planar direction with respect to acommunication partner device.

In Example 231, the subject matter of Example(s) 221-230 may includewherein the beam controller is configured to dynamically select betweenimplementing the beam scheme over the angular range and the selectivewidening or narrowing of at least one beam.

In Example 232, the subject matter of Example(s) 231 may include ameasurer configured to measure channel conditions, wherein the dynamicselection is based on the measured channel conditions.

In Example 233, the subject matter of Example(s) 231-232 may includewherein the beam controller is configured to determine betweenline-of-sight (LoS) channel conditions and multi-path channel conditionsbased on the measurement of one or more channel parameters.

In Example 234, the subject matter of Example(s) 233 may include whereina first of the one or more channel parameters is a delay spread measuredin one or more received signals.

In Example 235, the subject matter of Example(s) 234 may include whereinthe one or more received signals include one or more downlink signalsreceived from a base station, and the one or more downlink signals arespatially associated to one or more uplink channels.

In Example 236, the subject matter of Example(s) 235 may include whereinthe beam controller compares the delay spread to a predefined delayspread threshold.

In Example 237, the subject matter of Example(s) 236 may include whereinwhen the delay spread is greater than the threshold, the beam controllerdynamically selects the implementing the beam scheme over the angularrange.

In Example 238, the subject matter of Example(s) 236-237 may includewherein when the delay spread is less than the threshold, the beamcontroller dynamically selects the selective widening or narrowing of atleast one beam.

In Example 239, the subject matter of Example(s) 221-238 may include ameasurer configured to measure a link quality for one or more of theplurality of beams.

In Example 240, the subject matter of Example(s) 239 may include whereinthe beam controller is configured to control the beam scheme based onthe link quality of one or more of the plurality of beams.

In Example 241, the subject matter of Example(s) 221-240 may include theone or more antenna arrays.

In Example 242, the subject matter of Example(s) 221-241 may includewherein the predetermined time pattern is communicated with acommunication partner device.

In Example 243, a communication device including a controller configuredto control one or more antenna arrays including a plurality of antennaelements according to a receive scheme, the controller including adetector configured to detect a change in an angle of arrival of asignal; a subset controller configured to control a first subset ofantenna elements of the plurality of antenna elements to receive thesignal based on the detected change, wherein the first subset of antennaelements includes less antenna elements than the plurality of antennaelements; and a determiner configured to determine which of the antennaelements in the first subset of antenna elements reports a suitablereception strength and set the one or more antenna arrays to the receivescheme based on the determination.

In Example 244, the subject matter of Example(s) 243 may include whereinthe suitable signal strength is the highest signal strength.

In Example 245, the subject matter of Example(s) 243 may include whereinthe suitable signal strength is higher than a threshold.

In Example 246, the subject matter of Example(s) 243-245 may includewherein the subset controller is configured to control a second subsetof antenna elements, located within the first subset, to receive thesignal based on the second subset determination, and the determiner isconfigured to set the one or more antenna arrays to the receive schemebased on the second subset determination.

In Example 247, the subject matter of Example(s) 243-246 may includewherein the first subset includes about half of the antenna elements ofthe one or more antenna arrays.

In Example 248, the subject matter of Example(s) 243-246 may includewherein the first subset includes about one quarter of the antennaelements of the one or more antenna arrays.

In Example 249, the subject matter of Example(s) 243-246 may includewherein the first subset includes about one eighth of the antennaelements of the one or more antenna arrays.

In Example 250, the subject matter of Example(s) 246-249 may includewherein the second subset includes half the antenna elements of thefirst subset.

In Example 251, the subject matter of Example(s) 243-250 may include theone or more antenna arrays.

In Example 252, a communication device including one or more processorsconfigured to control one or more antenna arrays to generate a pluralityof beams according to a beam scheme, wherein the beam scheme implementsthe plurality of beams according to at least one of: over an angularrange with respect to the communication device, wherein a first beam ofthe plurality of beams has a different angle with respect to thecommunication device than a second beam of the plurality of beams, andeach beam of the plurality of beams is maintained based on apredetermined time pattern; or a selective widening or narrowing of atleast one beam of the plurality of beams with respect to another beam ofthe plurality of beams.

In Example 253, a communication device including one or more processorsconfigured to detect a change in an angle of arrival of a signal;control a first subset of antenna elements of the plurality of antennaelements to receive the signal based on the detected change, wherein thefirst subset of antenna elements includes less antenna elements than theplurality of antenna elements; and determine which of the antennaelements in the first subset of antenna elements reports a suitablereception strength and set the one or more antenna arrays to the receivescheme based on the determination.

In Example 254, a communication device including means to control one ormore antenna arrays to generate a plurality of beams according to a beamscheme, wherein the beam scheme implements the plurality of beamsaccording to at least one of: over an angular range with respect to thecommunication device, wherein a first beam of the plurality of beams hasa different angle with respect to the communication device than a secondbeam of the plurality of beams, and each beam of the plurality of beamsis maintained based on a predetermined time pattern; or a selectivewidening or narrowing of at least one beam of the plurality of beamswith respect to another beam of the plurality of beams.

In Example 255, a communication device including means to detect achange in an angle of arrival of a signal; means to control a firstsubset of antenna elements of the plurality of antenna elements toreceive the signal based on the detected change, wherein the firstsubset of antenna elements includes less antenna elements than theplurality of antenna elements; and means to determine which of theantenna elements in the first subset of antenna elements reports asuitable reception strength and set the one or more antenna arrays tothe receive scheme based on the determination.

In Example 256, a method including: making one or more measurements;controlling one or more antenna arrays to generate one or more beamsaccording to a beam scheme based on the one or more measurements,wherein the beam scheme implements the one or more beams according to atleast one of: over an angular range with respect to the communicationdevice, wherein a first beam of the one or more beams has a differentangle with respect to the communication device than a second beam of theone or more beams, and each beam of the one or more beams is maintainedbased on a predetermined time pattern, or a selective widening ornarrowing of at least one beam of the one or more beams.

In Example 257, the subject matter of Example(s) 256 may includeimplementing the one or more beams according to scheme over the angularrange and the selective widening or narrowing of the at least one beam.

In Example 258, the subject matter of Example(s) 256-257 may includewherein the one or more beams include a plurality of beams and whereineach of the plurality of beams' respective angles are selected from aplurality of angles in a predefined set.

In Example 259, the subject matter of Example(s) 258 may include whereineach angle in the predefined set has a discrete angular change withrespect to at least one other angle in the predefined set.

In Example 260, the subject matter of Example(s) 256-259 may includescheduling the plurality of beams to cover the angular range accordingto a round robin mechanism.

In Example 261, the subject matter of Example(s) 260 may includedetermining a repetition period of each cycle of the round robinmechanism based on a maximum power exposure (MPE) threshold.

In Example 262, the subject matter of Example(s) 261 may includedetermining the MPE threshold based on one or more regulations or rulesby a regulatory authority.

In Example 263, the subject matter of Example(s) 256-262 may includebasing the selective widening or narrowing of the at least one beam ofthe one or more beams on a maximum power exposure (MPE) threshold.

In Example 264, the subject matter of Example(s) 263 may include whereina total transmission power of the selective widening or narrowing of theat least one beam of the one or more beams with respect to another beamof the one or more beams remains the same.

In Example 265, the subject matter of Example(s) 263-264 may includewherein the widening or narrowing is performed in at least one of ahorizontal, a vertical, or a planar direction with respect to acommunication partner device.

In Example 266, the subject matter of Example(s) 256-265 may includedynamically selecting between implementing the beam scheme over theangular range or implementing the selective widening or narrowing of theat least one beam based on the one or more measurements.

In Example 267, the subject matter of Example(s) 266 may include whereinthe making one or more measurements includes measuring channelconditions and basing the dynamic selection on the measured channelconditions.

In Example 268, the subject matter of Example(s) 266-267 may includedetermining between line-of-sight (LoS) channel conditions andmulti-path channel conditions based on the measurement of one or morechannel parameters.

In Example 269, the subject matter of Example(s) 268 may include whereina first of the one or more channel parameters is a delay spread measuredin one or more received signals.

In Example 270, the subject matter of Example(s) 269 may include whereinthe one or more received signals include one or more downlink signalsreceived from a base station, and the one or more downlink signals arespatially associated to one or more uplink channels.

In Example 271, the subject matter of Example(s) 270 may includecomparing the delay spread to a predefined delay spread threshold.

In Example 272, the subject matter of Example(s) 271 may include whereinwhen the delay spread is greater than the threshold, further includingselecting implementing the beam scheme over the angular range.

In Example 273, the subject matter of Example(s) 271-272 may includewherein when the delay spread is less than the threshold, furtherincluding selecting implementing the selective widening or narrowing ofthe at least one beam.

In Example 274, the subject matter of Example(s) 256-273 may includewherein the making one or more measurements includes detecting anobstacle between the communication device and a communication partnerdevice.

In Example 275, the subject matter of Example(s) 274 may includecontrolling the beam scheme based on the detection of the obstacle.

In Example 276, the subject matter of Example(s) 256-275 may includecommunicating the predetermined time pattern with a communicationpartner device.

In Example 277, a method for controlling one or more antenna arraysincluding a plurality of antenna elements according to a receive scheme,the method including: detecting a change in an angle of arrival of asignal; controlling a first subset of antenna elements of the pluralityof antenna elements to receive the signal based on the detected change,wherein the first subset of antenna elements includes less antennaelements than the plurality of antenna elements; and determining whichof the antenna elements in the first subset of antenna elements reportsa suitable reception strength and set the one or more antenna arrays tothe receive scheme based on the determination.

In Example 278, the subject matter of Example(s) 277 may include whereinthe suitable signal strength is the highest signal strength.

In Example 279, the subject matter of Example(s) 277 may include whereinthe suitable signal strength is higher than a threshold.

In Example 280, the subject matter of Example(s) 277-279 may includecontrolling a second subset of antenna elements, located within thefirst subset, to receive the signal based on the second subsetdetermination, and setting the one or more antenna arrays to the receivescheme based on the second subset determination.

In Example 281, the subject matter of Example(s) 277-280 may includewherein the first subset includes about half of the antenna elements ofthe one or more antenna arrays.

In Example 282, the subject matter of Example(s) 277-280 may includewherein the first subset includes about one quarter of the antennaelements of the one or more antenna arrays.

In Example 283, the subject matter of Example(s) 277-280 may includewherein the first subset includes about one eighth of the antennaelements of the one or more antenna arrays.

In Example 284, the subject matter of Example(s) 277-283 may includewherein the second subset includes half the antenna elements of thefirst subset.

In Example 285, one or more non-transitory computer-readable mediastoring instructions thereon that, when executed by at least oneprocessor of a communication device, direct the communication device toperform the method of any one of Examples 256-284.

While the disclosure has been particularly shown and described withreference to specific aspects, it should be understood by those skilledin the art that various changes in form and detail may be made thereinwithout departing from the spirit and scope of the disclosure as definedby the appended claims. The scope of the disclosure is thus indicated bythe appended claims and all changes which come within the meaning andrange of equivalency of the claims are therefore intended to beembraced.

What is claimed is:
 1. A circuit arrangement comprising one or moreprocessors configured to: detect a presence of one or more human objectproximities based on sensor data; identify one or more coverage sectorsof one or more antenna arrays, operably coupled to the one or moreprocessors, in response to the detected presence of the one or morehuman object proximities; determine whether radio waves within the oneor more identified coverage sectors satisfy a transmit power criteria,wherein determining whether the radio waves of the one or moreidentified coverage sectors satisfy the transmit power criteriacomprises: evaluating, based on the detected presence of the one or morehuman object proximities in each of the one or more identified coveragesectors, a maximum transmit power for radio waves in the one or moreidentified coverage sectors, and forming a subset from the one or moreidentified coverage sectors whose radio waves' maximum transmit powerexceeds a threshold; select one or more candidate coverage sectors ofthe one or more antenna arrays based the one or more identified coveragesectors, wherein selecting the one or more candidate coverage sectors ofthe one or more antenna arrays comprises including the subset; anddetermine at least one radio link quality for the radio waves of the oneor more candidate coverage sectors.
 2. The circuit arrangement of claim1, wherein the one or more antenna arrays comprise a plurality ofantenna arrays, and the one or more processors are further configured toselect the one or more candidate coverage sectors by switching betweenthe plurality of antenna arrays.
 3. The circuit arrangement of claim 1,wherein the one or more processors are configured to detect the presenceof the one or more human object proximities based on the sensor data by:detecting Doppler or micro-Doppler effects in a received reflectedsignal from a signal transmitted by a communication device housing theone or more processors, or measuring, based on a received reflectedsignal from a signal transmitted by a communication device housing theone or more processors, a reflectivity of one or more objects across afrequency range to determine a frequency signature and comparing thefrequency signature with a pre-characterized human tissue frequencysignature.
 4. The circuit arrangement of claim 1, wherein the one ormore processors are configured to detect the presence of the one or morehuman object proximities based on the sensor data by: measuring, basedon a received reflected signal from a signal transmitted by acommunication device housing the one or more processors, a reflectivityof one or more objects across a temporal range to determine areflectivity signature and comparing the reflectivity signature with apre-characterized human tissue reflectivity signature.
 5. The circuitarrangement of claim 1, the one or more processors configured to selecta target coverage sector from the one or more candidate coverage sectorsbased on the determined radio link quality for each of the one or morecandidate coverage sectors, and to control the one or more antennaarrays to transmit or receive signals with the target coverage sector.6. A communication device comprising one or more processors configuredto: control one or more antenna arrays, operatively coupled to the oneor more processors, to communicate with a second device via adevice-side beam of a beam pair, wherein the second device communicateswith the communication device via a partner-side beam of the beam pair;evaluate one or more criteria; and update the beam pair based on theevaluation of the one or more criteria, wherein the one or moreprocessors adjusts the device-side beam to an updated device-side beamof the updated beam pair, and communicates an updated partner-side beamcorresponding to the updated device-side beam to the second device. 7.The communication device of claim 6, wherein the evaluation of the oneor more criteria comprises one or more of a detection of an object, amaximum power exposure (MPE) threshold to electromagnetic radiation, ora channel quality between the communication device and the second devicefor the beam pair.
 8. The communication device of claim 7, wherein theevaluation of the one or more criteria comprises determining whether theMPE threshold is exceeded in a direction of the detected object.
 9. Thecommunication device of claim 6, wherein the updated beam pair isselected from a plurality of candidate beam pairs.
 10. The communicationdevice of claim 9, wherein the updated beam pair is a beam pair having ahighest channel quality from the plurality of candidate beam pairs. 11.A circuit arrangement comprising one or more processors configured to:identify a high power limit window and a low power limit window, whereinthe high power limit window and/or the low power limit window aredetermined based on an exposure threshold, wherein the high power limitwindow and the low power limit window span a different time from oneanother; identify a first communication scheduled for transmission and asecond communication scheduled for transmission; determine a firsttransmission time for the first communication and a second transmissiontime for the second communication based on the exposure threshold andfurther based on a communication priority or a communication size,wherein the first communication has a higher priority or a largercommunication size than the second communication; and generate, fortransmission, the first communication at the first transmission timeduring the high power limit window and the second communication at thesecond transmission time during the low power limit window.
 12. Thecircuit arrangement of claim 11, wherein the first communicationcomprises a first data packet, and the second communication comprises asecond data packet.
 13. The circuit arrangement of claim 12, wherein thecommunication priority is a data packet priority between the first datapacket and the second data packet, and the communication size is a datapacket size of the first data packet and the second data packet.
 14. Thecircuit arrangement of claim 11, wherein the high power limit window hasa larger radio frequency (RF) power limit than the low power limitwindow.
 15. The circuit arrangement of claim 14, wherein the low powerlimit window is scheduled immediately after the high power limit window.16. A circuit arrangement comprising one or more processors configuredto: detect a change in an angle of arrival of a signal at an antennaarray module operatively coupled to one or more processors, wherein theantenna array module comprises a plurality of antenna elements; controla first subset of antenna elements of the plurality of antenna elementsto receive the signal based on the detected change, wherein the firstsubset of antenna elements comprises fewer antenna elements than theplurality of antenna elements, wherein the first subset of antennaelements comprises antenna elements that were receiving the signalbefore the detected change in the angle of arrival and one or moreneighboring antenna elements; and determine which of the antennaelements in the first subset of antenna elements report a highestreception strength and set the one or more antenna arrays to a receivescheme based on the determination.
 17. The circuit arrangement of claim16, the one or more processors further configured to control a secondsubset of antenna elements to receive the signal and measure which ofthe antenna elements in the second subset report a highest signalstrength.
 18. The circuit arrangement of claim 17, wherein the one ormore processors are configured to set the one or more antenna arrays tothe receive scheme based on the antenna elements in the second subsetreporting the highest signal strength.
 19. The circuit arrangement ofclaim 18, wherein the first subset includes a fraction of the antennaelements in the antenna array module, and the second subset includes afraction of the antenna elements in the first subset.